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| INTEGRATED CIRCUITS DATA SHEET SAF7118 Multistandard video decoder with adaptive comb filter and component video input Product specification Supersedes data of 2003 Jan 03 2004 Jul 22 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input CONTENTS 1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 2 3 4 5 6 7 8 8.1 8.2 8.3 8.4 8.5 8.6 8.7 9 9.1 9.2 9.3 9.4 9.5 9.6 9.7 9.8 FEATURES Video acquisition/clock Video decoder Component video processing Video scaler Vertical Blanking Interval (VBI) data decoder and slicer Audio clock generation Digital I/O interfaces Miscellaneous APPLICATIONS GENERAL DESCRIPTION QUICK REFERENCE DATA ORDERING INFORMATION BLOCK DIAGRAM PINNING FUNCTIONAL DESCRIPTION Decoder Component video processing Decoder output formatter Scaler VBI data decoder and capture (subaddresses 40H to 7FH) Image port output formatter (subaddresses 84H to 87H) Audio clock generation (subaddresses 30H to 3FH) INPUT/OUTPUT INTERFACES AND PORTS Analog terminals Audio clock signals Clock and real-time synchronization signals Interrupt handling Video expansion port (X port) Image port (I port) Host port for 16-bit extension of video data I/O (H port) Basic input and output timing diagrams I port and X port 10 10.1 10.2 11 12 13 14 15 15.1 15.2 15.3 15.4 15.5 15.6 15.7 16 16.1 16.2 16.3 16.4 16.5 17 18 18.1 18.2 18.3 18.4 18.5 19 20 21 22 BOUNDARY SCAN TEST SAF7118 Initialization of boundary scan circuit Device identification codes LIMITING VALUES THERMAL CHARACTERISTICS CHARACTERISTICS APPLICATION INFORMATION I2C-BUS DESCRIPTION I2C-bus format I2C-bus details Programming register RGB/Y-PB-PR component input processing Interrupt mask registers Programming register audio clock generation Programming register VBI data slicer Programming register interfaces and scaler part PROGRAMMING START SET-UP Decoder part Component video part and interrupt mask Audio clock generation part Data slicer and data type control part Scaler and interfaces PACKAGE OUTLINES SOLDERING Introduction to soldering surface mount packages Reflow soldering Wave soldering Manual soldering Suitability of surface mount IC packages for wave and reflow soldering methods DATA SHEET STATUS DEFINITIONS DISCLAIMERS PURCHASE OF PHILIPS I2C COMPONENTS 2004 Jul 22 2 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 1 1.1 FEATURES Video acquisition/clock SAF7118 * Up to sixteen analog CVBS, split as desired (all of the CVBS inputs optionally can be used to convert e.g. Vestigial Side Band (VSB) signals) * Up to eight analog Y + C inputs, split as desired * Up to four analog component inputs, with embedded or separate sync, split as desired * Four on-chip anti-aliasing filters in front of the Analog-to-Digital Converters (ADCs) * Automatic Clamp Control (ACC) for CVBS, Y and C (or VSB) and component signals * Switchable white peak control * Four 9-bit low noise CMOS ADCs running at twice the oversampling rate (27 MHz) * Fully programmable static gain or Automatic Gain Control (AGC), matching to the particular signal properties * On-chip line-locked clock generation in accordance with "ITU 601" * Requires only one crystal (32.11 or 24.576 MHz) for all standards * Horizontal and vertical sync detection. 1.2 Video decoder * Independent gain and offset adjustment for raw data path. 1.3 Component video processing * RGB component inputs * Y-PB-PR component inputs * Fast blanking between CVBS and synchronous component inputs * Digital RGB to Y-CB-CR matrix. 1.4 Video scaler * Horizontal and vertical downscaling and upscaling to randomly sized windows * Horizontal and vertical scaling range: variable zoom to 1 (icon) (it should be noted that the H and V zoom are 64 restricted by the transfer data rates) * Anti-alias and accumulating filter for horizontal scaling * Vertical scaling with linear phase interpolation and accumulating filter for anti-aliasing (6-bit phase accuracy) * Horizontal phase correct up and downscaling for improved signal quality of scaled data, especially for compression and video phone applications, with 6-bit phase accuracy (1.2 ns step width) * Two independent programming sets for scaler part, to define two `ranges' per field or sequences over frames * Fieldwise switching between decoder part and expansion port (X port) input * Brightness, contrast and saturation controls for scaled outputs. 1.5 Vertical Blanking Interval (VBI) data decoder and slicer * Digital PLL for synchronization and clock generation from all standards and non-standard video sources e.g. consumer grade VTR * Automatic detection of any supported colour standard * Luminance and chrominance signal processing for PAL B, G, D, H, I and N, combination PAL N, PAL M, NTSC M, NTSC-Japan, NTSC 4.43 and SECAM * Adaptive 2/4-line comb filter for two dimensional chrominance/luminance separation, also with VTR signals - Increased luminance and chrominance bandwidth for all PAL and NTSC standards - Reduced cross colour and cross luminance artefacts * PAL delay line for correcting PAL phase errors * Brightness Contrast Saturation (BCS) adjustment, separately for composite and baseband signals * User programmable sharpness control * Detection of copy-protected signals according to the Macrovision(1) standard, indicating level of protection * Versatile VBI data decoder, slicer, clock regeneration and byte synchronization e.g. for World Standard Teletext (WST), North American Broadcast Text System (NABTS), closed caption, Wide Screen Signalling (WSS), etc. (1) Macrovision is a registered trademark of the Macrovision Corporation. 2004 Jul 22 3 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 1.6 Audio clock generation 2 APPLICATIONS SAF7118 * Generation of a field-locked audio master clock to support a constant number of audio clocks per video field * Generation of an audio serial and left/right (channel) clock signal. 1.7 Digital I/O interfaces * PC-video capture and editing * Personal video recorders (time shifting) * Cable, terrestrial, and satellite set-top boxes * Internet terminals * Flat-panel monitors * DVD recordable players * AV-ready hard-disk drivers * Digital televisions/scan conversion * Video surveillance/security * Video editing/post production * Video phones * Video projectors * Digital VCRs. 3 GENERAL DESCRIPTION * Real-time signal port (R port), inclusive continuous line-locked reference clock and real-time status information supporting RTC level 3.1 (refer to document "RTC Functional Specification" for details) * Bidirectional expansion port (X port) with half duplex functionality (D1), 8-bit Y-CB-CR: - Output from decoder part, real-time and unscaled - Input to scaler part, e.g. video from MPEG decoder (extension to 16-bit possible) * Video image port (I port) configurable for 8-bit data (extension to 16-bit possible) in master mode (own clock), or slave mode (external clock), with auxiliary timing and handshake signals * Discontinuous data streams supported * 32-word x 4-byte FIFO register for video output data * 28-word x 4-byte FIFO register for decoded VBI data output * Scaled 4 : 2 : 2, 4 : 1 : 1, 4 : 2 : 0, 4 : 1 : 0 Y-CB-CR output * Scaled 8-bit luminance only and raw CVBS data output * Sliced, decoded VBI data output. 1.8 Miscellaneous The SAF7118 is a video capture device for applications at the image port of VGA controllers. Philips X-VIP is a new multistandard comb filter video decoder chip with additional component processing, providing high quality, optionally scaled, video. The SAF7118 is a combination of a four-channel analog preprocessing circuit including source selection, anti-aliasing filter and ADC with succeeding decimation filters from 27 to 13.5 MHz data rate. Each preprocessing channel comes with an automatic clamp and gain control. The SAF7118 combines a Clock Generation Circuit (CGC), a digital multistandard decoder containing two-dimensional chrominance/luminance separation by an adaptive comb filter and a high performance scaler, including variable horizontal and vertical up and downscaling and a brightness, contrast and saturation control circuit. * Power-on control * 5 V tolerant digital inputs and I/O ports * Software controlled power saving standby modes supported * Programming via serial I2C-bus, full read back ability by an external controller, bit rate up to 400 kbit/s * Boundary scan test circuit complies with the "IEEE Std. 1149.b1 - 1994". 2004 Jul 22 4 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input It is a highly integrated circuit for desktop video and similar applications. The decoder is based on the principle of line-locked clock decoding and is able to decode the colour of PAL, SECAM and NTSC signals into ITU 601 compatible colour component values. The SAF7118 accepts CVBS or S-video (Y/C) as analog inputs from TV or VCR sources, including weak and distorted signals as well as baseband component signals Y-PB-PR or RGB. An expansion port (X port) for digital video (bidirectional half duplex, D1 compatible) is also supported to connect to MPEG or a video phone codec. At the so called image port (I port) the SAF7118 supports 8 or 16-bit wide output data with auxiliary reference data for interfacing to VGA controllers. The target application for the SAF7118 is to capture and scale video images, to be provided as a digital video stream through the image port of a VGA controller, for capture to system memory, or just to provide digital baseband video to any picture improvement processing. 4 QUICK REFERENCE DATA SYMBOL VDDD VDDD(C) VDDA Tamb PA+D Note PARAMETER digital supply voltage digital core supply voltage analog supply voltage ambient temperature analog and digital power dissipation note 1 CONDITIONS MIN. 3.0 3.0 3.1 -40 - TYP. 3.3 3.3 3.3 - 1.1 SAF7118 The SAF7118 also provides a means for capturing the serially coded data in the vertical blanking interval (VBI data). Two principal functions are available: 1. To capture raw video samples, after interpolation to the required output data rate, via the scaler 2. A versatile data slicer (data recovery) unit. The SAF7118 also incorporates field-locked audio clock generation. This function ensures that there is always the same number of audio samples associated with a field, or a set of fields. This prevents the loss of synchronization between video and audio during capture or playback. All of the ADCs may be used to digitize a VSB signal for subsequent decoding; a dedicated output port and a selectable VSB clock input is provided. The circuit is I2C-bus controlled (full write/read capability for all programming registers, bit rate up to 400 kbit/s). MAX. 3.6 3.6 3.5 +85 1.35 V V V C W UNIT 1. Power dissipation is measured in component mode (four ADCs active) and 8-bit image port output mode, expansion port is 3-stated. 5 ORDERING INFORMATION TYPE NUMBER PACKAGE NAME DESCRIPTION VERSION SOT807-1 SOT322-2 SAF7118EH HBGA156 plastic thermal enhanced ball grid array package; 156 balls; body 15 x 15 x 1.15 mm; heatsink SAF7118H QFP160 plastic quad flat package; 160 leads (lead length 1.6 mm); body 28 x 28 x 3.4 mm; high stand-off height 2004 Jul 22 5 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 ADP [8:0] CLKEXT CE RES DNC0 to DNC5 SDA SCL INT_A AD PORT CONTROL I2C-BUS REGISTER MAP FIRST TASK I2C-BUS REGISTER MAP SCALER SECOND TASK I2C-BUS REGISTER MAP SCALER FSW AI11 AI12 AI13 AI14 AI1D AI21 AI22 AI23 AI24 AI2D ANALOG1 ADC1 DF R G B ANALOG2 ADC2 DF COMPONENTS PROCESSING RAW ANALOG INPUT CONTROL 6 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input BLOCK DIAGRAM FAST SWITCH DELAY Y CB CR DECODER OUTPUT CONTROL SCALER EVENT CONTROLLER HORIZONTAL FINE (PHASE) SCALING VERTICAL SCALING LINE FIFO BUFFER C CROMINANCE PROCESSING CR Y-CB-CR AI31 AI32 AI33 AI34 AI3D AI41 AI42 AI43 AI44 AI4D AOUT AGND AGNDA ANALOG3 ADC3 DF COMB FILTER VIDEO FIFO CB OUTPUT FORMATTER I PORT FIR-PREFILTER PRESCALER BCS-SCALER S IGP1 IGP0 IGPV IGPH IPD [7:0] 6 6 SAF7118 RAW Y-CB-CR TEXT FIFO VBI-DATA SLICER Y S LUMININANCE PROCESSING S S SYNCHRONIZATION Y ICLK IDQ ITRDY ITRI ANALOG4 ADC4 DF S CB-CR Y-CB-CRS CB-CR VIDEO/TEXT ARBITER POWER-ON CONTROL POWER SUPPLY VIDEO CLOCK GPO CRYSTAL X PORT H PORT AUDIO CLOCK BOUNDARY SCAN mbl751 VSSA VSSD VDDA VDD(xtal) LLC2 VSS(xtal) VDDD LLC RTS0 RTCO XTALI XRDY XCLK XDQ XRH XRV XTRI AMXCLK ALRCLK HPD [7:0] AMCLK TDO TDI TRST TCK TMS Product specification RTS1 XTALO XTOUT XPD [7:0] ASCLK SAF7118 SAF7118 Fig.1 Block diagram. Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 7 PINNING PIN SYMBOL QFP160 HBGA156 DNC6 AI41 AGND VSSA4 AI42 AI4D AI43 VDDA4 VDDA4A AI44 AI31 VSSA3 AI32 AI3D AI33 VDDA3 VDDA3A AI34 AI21 VSSA2 AI22 AI2D AI23 VDDA2 VDDA2A AI24 AI11 VSSA1 AI12 AI1D AI13 VDDA1 VDDA1A AI14 AGNDA AOUT VDDA0 VSSA0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 B2 B1 C2 C1 D2 D3 D1 D4 E2 E1 E3 E4 F2 F1 F3 F4 G2 G1 G4 H3 G3 H1 H2 H4 J1 J3 J2 J4 K1 K3 K2 K4 L1 L3 L2 M1 M3 M2 O I P P I I I P P I I P I I/O I P P I I P I I I P P I I P I I I P P I P O P P TYPE(1) DESCRIPTION SAF7118 do not connect, reserved for future extensions and for testing analog input 41 analog ground ground for analog inputs AI4x analog input 42 differential input for ADC channel 4 (pins AI41 to AI44) analog input 43 analog supply voltage for analog inputs AI4x (3.3 V) analog supply voltage for analog inputs AI4x (3.3 V) analog input 44 analog input 31 ground for analog inputs AI3x analog input 32 differential input for ADC channel 3 (pins AI31 to AI34) analog input 33 analog supply voltage for analog inputs AI3x (3.3 V) analog supply voltage for analog inputs AI3x (3.3 V) analog input 34 analog input 21 ground for analog inputs AI2x analog input 22 differential input for ADC channel 2 (pins AI24 to AI21) analog input 23 analog supply voltage for analog inputs AI2x (3.3 V) analog supply voltage for analog inputs AI2x (3.3 V) analog input 24 analog input 11 ground for analog inputs AI1x analog input 12 differential input for ADC channel 1 (pins AI14 to AI11) analog input 13 analog supply voltage for analog inputs AI1x (3.3 V) analog supply voltage for analog inputs AI1x (3.3 V) analog input 14 analog signal ground analog test output (do not connect) analog supply voltage (3.3 V) for internal clock generation circuit ground for internal Clock Generation Circuit (CGC) 2004 Jul 22 7 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input PIN SYMBOL QFP160 HBGA156 DNC13 DNC14 DNC18 DNC15 EXMCLR CE VDDD1 LLC VSSD1 LLC2 RES VDDD2 VSSD2 CLKEXT ADP8 ADP7 ADP6 ADP5 ADP4 ADP3 VDDD3 ADP2 ADP1 ADP0 VSSD3 INT_A VDDD4 SCL VSSD4 SDA RTS0 RTS1 RTCO 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 N1 N2 P2 N3 P3 N4 M4 P4 L4 N5 P5 M5 L5 N6 P6 M6 L6 N7 P7 L7 M8 M7 P8 N8 L8 P9 M9 N9 L9 P10 M10 N10 L10 NC I/pu I/O I/pd I/pd I/pu P O P O O P P I O O O O O O P O O O P O/od P I P I/O/od O O SAF7118 TYPE(1) DESCRIPTION do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing external mode clear (with internal pull-down) chip enable or reset input (with internal pull-up) digital supply voltage 1 (peripheral cells) line-locked system clock output (27 MHz nominal) digital ground 1 (peripheral cells) line-locked 12 clock output (13.5 MHz nominal) reset output (active LOW) digital supply voltage 2 (core) digital ground 2 (core; substrate connection) external clock input intended for analog-to-digital conversion of VSB signals (36 MHz) MSB of direct analog-to-digital converted output data (VSB) MSB - 1 of direct analog-to-digital converted output data (VSB) MSB - 2 of direct analog-to-digital converted output data (VSB) MSB - 3 of direct analog-to-digital converted output data (VSB) MSB - 4 of direct analog-to-digital converted output data (VSB) MSB - 5 of direct analog-to-digital converted output data (VSB) digital supply voltage 3 (peripheral cells) MSB - 6 of direct analog-to-digital converted output data (VSB) MSB - 7 of direct analog-to-digital converted output data (VSB) LSB of direct analog-to-digital converted output data (VSB) digital ground 3 (peripheral cells) I2C-bus interrupt flag (LOW if any enabled status bit has changed) digital supply voltage 4 (core) serial clock input (I2C-bus) digital ground 4 (core) serial data input/output (I2C-bus) real-time status or sync information, controlled by subaddresses 11H and 12H real-time status or sync information, controlled by subaddresses 11H and 12H O/st/pd real-time control output; contains information about actual system clock frequency, field rate, odd/even sequence, decoder status, subcarrier frequency and phase and PAL sequence (see document "RTC Functional Description", available on request); the RTCO pin is enabled via I2C-bus bit RTCE; see notes 5, 6 and Table 36 O audio master clock output, up to 50% of crystal clock 8 AMCLK 2004 Jul 22 72 P11 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input PIN SYMBOL QFP160 HBGA156 VDDD5 ASCLK ALRCLK 73 74 75 M11 N11 P12 P O digital supply voltage 5 (peripheral cells) audio serial clock output SAF7118 TYPE(1) DESCRIPTION O/st/pd audio left/right clock output; can be strapped to supply via a 3.3 k resistor to indicate that the default 24.576 MHz crystal (ALRCLK = 0; internal pull-down) has been replaced by a 32.110 MHz crystal (ALRCLK = 1); notes 5 and 7 I I/pu I/pu NC NC NC NC I/pd I/O O I/(O) audio master external clock input target ready input for image port data do not connect, reserved for future extensions and for testing: scan input do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing fast switch (blanking) with internal pull-down inserts component inputs into CVBS signal clock output signal for image port, or optional asynchronous back-end clock input output data qualifier for image port (optional: gated clock output) image port output control signal, affects all input port pins inclusive ICLK, enable and active polarity is under software control (bits IPE in subaddress 87H); output path used for testing: scan output general purpose output signal 0; image port (controlled by subaddresses 84H and 85H) digital ground 5 (peripheral cells) general purpose output signal 1; image port (controlled by subaddresses 84H and 85H) multi purpose vertical reference output signal; image port (controlled by subaddresses 84H and 85H) multi purpose horizontal reference output signal; image port (controlled by subaddresses 84H and 85H) MSB of image port data output MSB - 1 of image port data output MSB - 2 of image port data output digital supply voltage 6 (core) digital ground 6 (core) MSB - 3 of image port data output MSB - 4 of image port data output MSB - 5 of image port data output MSB - 6 of image port data output digital supply voltage 7 (peripheral cells) LSB of image port data output AMXCLK ITRDY DNC0 DNC16 DNC17 DNC19 DNC20 FSW ICLK IDQ ITRI 76 77 78 79 80 81 82 83 84 85 86 M12 N12 P13 N13 N14 - - M13 M14 L13 L12 IGP0 VSSD5 IGP1 IGPV IGPH IPD7 IPD6 IPD5 VDDD6 VSSD6 IPD4 IPD3 IPD2 IPD1 VDDD7 IPD0 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 L14 L11 K13 K14 K12 K11 J13 J14 J12 J11 H13 H14 H11 G12 H12 G14 O P O O O O O O P P O O O O P O 2004 Jul 22 9 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input PIN SYMBOL QFP160 HBGA156 HPD7 VSSD7 HPD6 VDDD8 HPD5 VSSD8 HPD4 HPD3 HPD2 HPD1 HPD0 VDDD9 DNC1 DNC2 DNC7 DNC8 DNC11 DNC12 DNC21 DNC22 DNC3 DNC4 DNC5 XTRI 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 G13 G11 F14 F12 F13 F11 E14 E12 E13 E11 D14 D12 D13 C14 B13 B14 C12 C13 - - A13 B12 A12 B11 I/O P I/O P I/O P I/O I/O I/O I/O I/O P I/pu I/pu NC NC NC NC NC NC I/pu O I/pu I SAF7118 TYPE(1) DESCRIPTION MSB of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port digital ground 7 (peripheral cells) MSB - 1 of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port digital supply voltage 8 (core) MSB - 2 of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port digital ground 8 (core) MSB - 3 of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port MSB - 4 of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port MSB - 5 of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port MSB - 6 of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port LSB of host port data I/O, extended CB-CR input for expansion port, extended CB-CR output for image port digital supply voltage 9 (peripheral cells) do not connect, reserved for future extensions and for testing: scan input do not connect, reserved for future extensions and for testing: scan input do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing: scan input do not connect, reserved for future extensions and for testing: scan output do not connect, reserved for future extensions and for testing: scan input X port output control signal, affects all X port pins (XPD7 to XPD0, XRH, XRV, XDQ and XCLK), enable and active polarity is under software control (bits XPE in subaddress 83H) MSB of expansion port data MSB - 1 of expansion port data digital ground 9 (peripheral cells) MSB - 2 of expansion port data MSB - 3 of expansion port data digital supply voltage 10 (core) digital ground 10 (core) XPD7 XPD6 VSSD9 XPD5 XPD4 VDDD10 VSSD10 127 128 129 130 131 132 133 C11 A11 D11 B10 A10 C10 D10 I/O I/O P I/O I/O P P 2004 Jul 22 10 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input PIN SYMBOL QFP160 HBGA156 XPD3 XPD2 VDDD11 VSSD11 XPD1 XPD0 XRV XRH VDDD12 XCLK XDQ VSSD12 XRDY TRST TCK TMS TDO VDDD13 TDI VSSD13 VSS(xtal) XTALI XTALO VDD(xtal) XTOUT DNC9 DNC10 Notes 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 B9 A9 C9 D9 B8 A8 D8 C7 C8 A7 B7 D7 A6 C6 B6 D6 A5 C5 B5 D5 A4 B4 A3 B3 A2 C3 C4 I/O I/O P P I/O I/O I/O I/O P I/O I/O P O I/pu I/pu I/pu O P I/pu P P I O P O NC NC MSB - 4 of expansion port data MSB - 5 of expansion port data digital supply voltage 11 (peripheral cells) digital ground 11 (peripheral cells) MSB - 6 of expansion port data LSB of expansion port data vertical reference I/O expansion port horizontal reference I/O expansion port digital supply voltage 12 (core) clock I/O expansion port data qualifier for expansion port digital ground 12 (core) task flag or ready signal from scaler, controlled by XRQT SAF7118 TYPE(1) DESCRIPTION test reset input (active LOW), for boundary scan test (with internal pull-up); notes 2, 3 and 4 test clock for boundary scan test; note 2 test mode select input for boundary scan test or scan test; note 2 test data output for boundary scan test; note 2 digital supply voltage 13 (peripheral cells) test data input for boundary scan test; note 2 digital ground 13 (peripheral cells) ground for crystal oscillator input terminal for 24.576 MHz (32.11 MHz) crystal oscillator or connection of external oscillator with TTL compatible square wave clock signal 24.576 MHz (32.11 MHz) crystal oscillator output; not connected if TTL clock input of XTALI is used supply voltage for crystal oscillator crystal oscillator output signal; auxiliary signal do not connect, reserved for future extensions and for testing do not connect, reserved for future extensions and for testing 1. I = input, O = output, P = power, NC = not connected, st = strapping, pu = pull-up, pd = pull-down, od = open-drain. 2. In accordance with the "IEEE1149.1" standard the pads TDI, TMS, TCK and TRST are input pads with an internal pull-up transistor and TDO is a 3-state output pad. 3. For board design without boundary scan implementation connect the TRST pin to ground. 4. This pin provides easy initialization of the Boundary Scan Test (BST) circuit. TRST can be used to force the Test Access Port (TAP) controller to the TEST_LOGIC_RESET state (normal operation) at once. 5. Pin strapping is done by connecting the pin to the supply via a 3.3 k resistor. During the power-up reset sequence the corresponding pins are switched to input mode to read the strapping level. For the default setting no strapping resistor is necessary (internal pull-down). 2004 Jul 22 11 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 6. Pin RTCO operates as I2C-bus slave address pin; RTCO = 0 slave address 42H/43H (default); RTCO = 1 slave address 40H/41H. 7. Pin ALRCLK: 0 = 24.576 MHz crystal (default); 1 = 32.110 MHz crystal. handbook, full pagewidth 157 VDD(xtal) 156 XTALO 154 VSS(xtal) 153 VSSD13 151 VDDD13 142 VDDD12 141 XRH 136 VDDD11 135 XPD2 132 VDDD10 131 XPD4 145 VSSD12 144 XDQ 137 VSSD11 133 VSSD10 158 XTOUT 129 VSSD9 160 DNC10 122 DNC22 121 DNC21 120 DNC12 119 DNC11 118 DNC8 117 DNC7 116 DNC2 115 DNC1 114 VDDD9 113 HPD0 112 HPD1 111 HPD2 110 HPD3 109 HPD4 108 VSSD8 107 HPD5 106 VDDD8 105 HPD6 104 VSSD7 103 HPD7 102 IPD0 101 VDDD7 100 IPD1 99 IPD2 98 IPD3 97 IPD4 96 VSSD6 95 VDDD6 94 IPD5 93 IPD6 92 IPD7 91 IGPH 90 IGPV 89 IGP1 88 VSSD5 87 IGP0 86 ITRI 85 IDQ 84 ICLK 83 FSW 82 DNC20 81 DNC19 DNC17 80 MBL752 155 XTALI 159 DNC9 146 XRDY 125 DNC5 AMXCLK 76 124 DNC4 ITRDY 77 DNC6 AI41 AGND VSSA4 AI42 AI4D AI43 VDDA4 VDDA4A AI44 AI31 VSSA3 AI32 AI3D AI33 VDDA3 VDDA3A AI34 AI21 VSSA2 AI22 AI2D AI23 VDDA2 VDDA2A AI24 AI11 VSSA1 AI12 AI1D AI13 VDDA1 VDDA1A AI14 AGNDA AOUT VDDA0 VSSA0 DNC13 DNC14 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 DNC18 41 DNC15 42 EXMCLR 43 CE 44 VDDD1 45 LLC 46 VSSD1 47 LLC2 48 RES 49 VDDD2 50 VSSD2 51 CLKEXT 52 ADP8 53 ADP7 54 ADP6 55 ADP5 56 ADP4 57 ADP3 58 VDDD3 59 ADP2 60 ADP1 61 ADP0 62 VSSD3 63 INT_A 64 VDDD4 65 SCL 66 VSSD4 67 SDA 68 RTS0 69 RTS1 70 RTCO 71 AMCLK 72 VDDD5 73 ASCLK 74 ALRCLK 75 DNC0 78 DNC16 79 SAF7118H Fig.2 Pin configuration (QFP160). 2004 Jul 22 12 123 DNC3 143 XCLK 139 XPD0 138 XPD1 134 XPD3 130 XPD5 128 XPD6 127 XPD7 147 TRST 126 XTRI 150 TDO 149 TMS 140 XRV 152 TDI 148 TCK Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 ball A1 index area 1 2 3 4 5 6 7 8 9 10 11 12 13 14 A B C D E F G H J K L M N P SAF7118EH 001aab338 Transparent top view Fig.3 Pin configuration (HBGA156). 2004 Jul 22 13 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... Table 1 Pin assignment (top view) 2004 Jul 22 2004 Jul 22 14 14 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input 1 A B C D E F G H J K L M N P AI41 VSSA4 AI43 AI44 AI3D AI34 AI2D VDDA2A AI12 VDDA1A AOUT 2 XTOUT TEST3 AGND AI42 VDDA4A AI32 VDDA3A AI23 AI11 AI13 AGNDA VSSA0 3 XTALO VDD(xtal) TEST7 AI4D AI31 AI33 AI22 VSSA2 AI24 AI1D AI14 VDDA0 4 VSS(xtal) XTALI TEST8 VDDA4 VSSA3 VDDA3 AI21 VDDA2 VSSA1 VDDA1 VSSD1 VDDD1 CE LLC 5 TDO TDI VDDD13 VSSD13 6 XRDY TCK TRST TMS 7 XCLK XDQ XRH VSSD12 8 XPD0 XPD1 VDDD12 XRV 9 XPD2 XPD3 VDDD11 VSSD11 10 XPD4 XPD5 VDDD10 VSSD10 11 XPD6 XTRI XPD7 VSSD9 HPD1 VSSD8 VSSD7 IPD2 VSSD6 IPD7 12 TEST1 TEST4 TEST9 VDDD9 HPD3 VDDD8 IPD1 VDDD7 VDDD6 IGPH ITRI 13 TEST2 TEST5 14 TEST6 TEST10 TEST11 TEST12 HPD2 HPD5 HPD7 IPD4 IPD6 IGP1 IDQ FSW HPD0 HPD4 HPD6 IPD0 IPD3 IPD5 IGPV IGP0 ICLK VSSD2 VDDD2 LLC2 RES ADP6 ADP7 CLKEXT ADP8 ADP3 ADP2 ADP5 ADP4 VSSD3 VDDD3 ADP0 ADP1 VSSD4 VDDD4 SCL INT_A RTCO RTS0 RTS1 SDA VSSD5 VDDD5 AMXCLK ASCLK ITRDY Product specification TEST13 TEST14 TEST15 TEST18 EXMCLR TEST16 TEST17 SAF7118 SAF7118 AMCLK ALRCLK TEST19 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... Table 2 8-bit/16-bit and alternative pin function configurations 2004 Jul 22 2004 Jul 22 15 15 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input PIN(1) SYMBOL 8-BIT INPUT MODES D1 data input 16-BIT INPUT MODES (ONLY FOR I2C-BUS PROGRAMMING) Y data input ALTERNATIVE INPUT FUNCTIONS 8-BIT OUTPUT MODES D1 decoder output 16-BIT OUTPUT MODES (ONLY FOR I2C-BUS PROGRAMMING) ALTERNATIVE OUTPUT FUNCTIONS I/O CONFIGURATION PROGRAMMING BITS XCODE[92H[3]] XPE[1:0] 83H[1:0] + pin XTRI C11, XPD7 to A11, XPD0 B10, A10, B9, A9, B8, A8 (127, 128, 130, 131, 134, 135, 138, 139) A7 (143) XCLK clock input gated clock input decoder clock output data qualifier output (HREF and VREF gate) XPE[1:0] 83H[1:0] + pin XTRI XPCK[1:0] 83H[5:4] XCKS[92H[0]] XDQ[92H[1]] XPE[1:0] 83H[1:0] + pin XTRI B7 (144) XDQ data qualifier input A6 (146) XRDY input ready output horizontal reference input vertical reference input output enable input active task A/B flag decoder horizontal reference output decoder vertical reference output XRQT[83H[2]] XPE[1:0] 83H[1:0] + pin XTRI XDH[92H[2]] XPE[1:0] 83H[1:0] + pin XTRI XDV[1:0] 92H[5:4] XPE[1:0] 83H[1:0] + pin XTRI XPE[1:0] 83H[1:0] Product specification C7 (141) XRH D8 (140) XRV SAF7118 SAF7118 B11 (126) XTRI This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 16 16 Philips Semiconductors 8-BIT INPUT MODES 16-BIT INPUT MODES (ONLY FOR I2C-BUS PROGRAMMING) CB-CR data input ALTERNATIVE INPUT FUNCTIONS 8-BIT OUTPUT MODES 16-BIT OUTPUT MODES (ONLY FOR I2C-BUS PROGRAMMING) CB-CR scaler output ALTERNATIVE OUTPUT FUNCTIONS I/O CONFIGURATION PROGRAMMING BITS ICODE[93H[7]] ISWP[1:0] 85H[7:6] I8_16[93H[6]] IPE[1:0] 87H[1:0] + pin ITRI Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input PIN(1) SYMBOL HPD7 to G13, HPD0 F14, F13, E14, E12, E13, E11, D14 (103, 105, 107, 109 to 113) K11, IPD7 to J13, J14, IPD0 H13, H14, H11, G12, G14 (92 to 94, 97 to 99, 100, 102) M14 (84) ICLK D1 scaler output Y scaler output ICODE[93H[7]] ISWP[1:0] 85H[7:6] I8_16[93H[6]] IPE[1:0] 87H[1:0] + pin ITRI clock output data qualifier output target ready input H gate output clock input ICKS[1:0] 80H[1:0] IPE[1:0] 87H[1:0] + pin ITRI ICKS[3:2] 80H[3:2] IDQP[85H[0]] IPE[1:0] 87H[1:0] + pin ITRI Product specification L13 (85) IDQ gated clock output N12 (77) K12 (91) ITRDY IGPH SAF7118 SAF7118 extended H gate, horizontal pulses IDH[1:0] 84H[1:0] IRHP[85H[1]] IPE[1:0] 87H[1:0] + pin ITRI This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 17 17 Philips Semiconductors 8-BIT INPUT MODES 16-BIT INPUT MODES (ONLY FOR I2C-BUS PROGRAMMING) ALTERNATIVE INPUT FUNCTIONS 8-BIT OUTPUT MODES V gate output 16-BIT OUTPUT MODES (ONLY FOR I2C-BUS PROGRAMMING) ALTERNATIVE OUTPUT FUNCTIONS V-sync, vertical pulses I/O CONFIGURATION PROGRAMMING BITS IDV[1:0] 84H[3:2] IRVP[85H[2]] IPE[1:0] 87H[1:0] + pin ITRI IDG1[1:0] 84H[5:4] IG1P[85H[3]] IPE[1:0] 87H[1:0] + pin ITRI IDG0[1:0] 84H[7:6] IG0P[85H[4]] IPE[1:0] 87H[1:0] + pin ITRI Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input PIN(1) SYMBOL K14 (90) IGPV K13 (89) IGP1 general purpose L14 (87) IGP0 general purpose L12 (86) ITRI output enable input Note 1. Pin numbers for QFP160 in parenthesis. Product specification SAF7118 SAF7118 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8 8.1 8.1.1 FUNCTIONAL DESCRIPTION Decoder ANALOG INPUT PROCESSING SAF7118 The anti-alias filters are adapted to the line-locked clock frequency via a filter control circuit. The characteristic is shown in Fig.4. During the vertical blanking period gain and clamping control are frozen. The SAF7118 offers sixteen analog signal inputs, four analog main channels with source switch, clamp circuit, analog amplifier, anti-alias filter and video 9-bit CMOS ADC with a Decimation Filter (DF); see Figs 5 and 8. MGD138 6 V (dB) 0 -6 -12 -18 -24 -30 -36 -42 0 2 4 6 8 10 12 f (MHz) 14 Fig.4 Anti-alias filter. 2004 Jul 22 18 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, full pagewidth 6 MBL753 G (dB) 0 -6 -12 -18 -24 -30 -36 -42 -48 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 f (MHz) Fig.5 Decimation filter. 2004 Jul 22 19 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.1.1.1 Clamping SAF7118 The clamp control circuit controls the correct clamping of the analog input signals. The coupling capacitor is also used to store and filter the clamping voltage. An internal digital clamp comparator generates the information with respect to clamp-up or clamp-down. The clamping levels for the four ADC channels are fixed for luminance (120), chrominance (256) and for component inputs as component Y (32), components PB and PR (256) or components RGB (32). Clamping time in normal use is set with the HCL pulse on the back porch of the video signal. 8.1.1.2 Gain control The AGC (automatic gain control for luminance) is used to amplify a CVBS or Y signal to the required signal amplitude, matched to the ADCs input voltage range. Component inputs are gain adjusted manually at a fixed gain. The AGC active time is the sync bottom of the video signal. Signal (white) peak control limits the gain at signal overshoots. The flow charts (see Figs 9 and 10) show more details of the AGC. The influence of supply voltage variation within the specified range is automatically eliminated by clamp and automatic gain control. The gain control circuit receives (via the I2C-bus) the static gain levels for the four analog amplifiers or controls one of these amplifiers automatically via a built-in Automatic Gain Control (AGC) as part of the Analog Input Control (AICO). handbook, halfpage TV line analog line blanking analog input level +3 dB maximum controlled ADC input level 511 GAIN 120 1 CLAMP 0 dB (1 V (p-p) 18/56 ) -6 dB range 9 dB 0 dB minimum MHB325 HCL HSY MHB726 Fig.6 Analog line with clamp (HCL) and gain range (HSY). Fig.7 Automatic gain range. 2004 Jul 22 20 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, full pagewidth TEST SELECTOR AND BUFFER DIGITAL TEST SELECTOR AOUT AOSL[2:0] ADP[8:0] AI44 AI43 AI42 AI41 AI4D SOURCE SWITCH CLAMP CIRCUIT ANALOG AMPLIFIER DAC9 ANTI-ALIAS FILTER BYPASS SWITCH DOSL[1:0] ADPE ADC4 FUSE[1:0] AI34 AI33 AI32 AI31 AI3D ANALOG AMPLIFIER DAC9 SOURCE SWITCH CLAMP CIRCUIT ANTI-ALIAS FILTER BYPASS SWITCH ADC3 FUSE[1:0] AI24 AI23 AI22 AI21 AI2D ANALOG AMPLIFIER DAC9 SOURCE SWITCH CLAMP CIRCUIT ANTI-ALIAS FILTER BYPASS SWITCH ADC2 FUSE[1:0] AI14 AI13 AI12 AI11 AI1D ANALOG AMPLIFIER DAC9 SOURCE SWITCH CLAMP CIRCUIT ANTI-ALIAS FILTER BYPASS SWITCH ADC1 FUSE[1:0] MODE CONTROL CLAMP CONTROL GAIN CONTROL ANTI-ALIAS CONTROL VERTICAL BLANKING CONTROL MODE[5:0] HCL GLIMB HSY GLIMT WIPA SLTCA HOLDG GAFIX WPOFF GUDL[1:0] GAI[48:40] GAI[38:30] HLNRS UPTCV REFA VBSL VBLNK SVREF 9 9 9 9 DF DF DF DF ANALOG CONTROL CROSS MULTIPLEXER 9 CVBS/Y 9 CHROMA 9 R/R - Y 9 G/Y 9 B/B - Y 9 9 AD2/4BYP AD1/3BYP MBL758 Fig.8 Analog input processing using the SAF7118 as differential front-end with 9-bit ADC. 2004 Jul 22 21 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, full pagewidth ANALOG INPUT AMPLIFIER ANTI-ALIAS FILTER ADC 9 LUMA/CHROMA DECODER gain DAC 9 NO ACTION 1 VBLK 1 0 0 HOLDG 1 X 1 0 0 HSY 0 0 1 > 510 1 1 0 1 0 <4 <1 > 510 X=0 1 > 496 0 X=1 +1/F STOP +1/L -1/LLC2 +1/LLC2 -1/LLC2 +/- 0 GAIN ACCUMULATOR (18 BITS) ACTUAL GAIN VALUE 9-BIT (AGV) [-3/+6 dB] 1 0 1 X HSY 1 0 0 Y AGV X = system variable. Y = AGV - FGV > GUDL . GUDL = gain update level (adjustable). VBLK = vertical blanking pulse. HSY = horizontal sync pulse. AGV = actual gain value. FGV = frozen gain value. UPDATE FGV GAIN VALUE 9-BIT MHB728 Fig.9 Gain flow chart. 2004 Jul 22 22 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 ANALOG INPUT ADC NO BLANKING ACTIVE 1 VBLK 0 <- CLAMP GAIN -> 1 HCL 0 1 HSY 0 1 CLL 0 0 SBOT 1 1 WIPE 0 + CLAMP - CLAMP NO CLAMP + GAIN - GAIN fast - GAIN slow + GAIN MGC647 WIPE = white peak level (510). SBOT = sync bottom level (1). CLL = clamp level [120 for CVBS, Y(C), S; 256 for C(Y), PB-PR; 32 for RGB, Y]. HSY = horizontal sync pulse. HCL = horizontal clamp pulse. Fig.10 Clamp and gain flow chart. 2004 Jul 22 23 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... ndbook, full pagewidth 2004 Jul 22 2004 Jul 22 CVBS-IN or Y-IN LDEL YCOMB DELAY COMPENSATION CHR QUADRATURE MODULATOR CB-CR LUBW CVBS-IN or CHR-IN QUADRATURE DEMODULATOR LOW-PASS 1 DOWNSAMPLING SUBCARRIER GENERATION 2 LCBW [ 2:0] 8.1.2 CHROMINANCE AND LUMINANCE PROCESSING Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input Y SUBTRACTOR LUMINANCE-PEAKING OR LOW-PASS, Y-DELAY ADJUSTMENT Y/CVBS DBRI [ 7:0] DCON [ 7:0] DSAT [ 7:0] RAWG [ 7:0] RAWO [ 7:0] COLO INTERPOLATION LOW-PASS 3 LUFI [ 3:0] CSTD [ 2:0] YDEL [ 2:0] SET_RAW SET_VBI CB-CR ADAPTIVE COMB FILTER CB-CR LOW-PASS 2 BRIGHTNESS CONTRAST SATURATION CONTROL RAW DATA GAIN AND OFFSET CONTROL Y-OUT/ CVBS OUT CB-CR -OUT HREF-OUT SET_RAW CCOMB SET_VBI YCOMB LDEL BYPS CHBW 24 24 SUBCARRIER GENERATION 1 HUEC CHROMINANCE INCREMENT DELAY LDEL YCOMB SECAM PROCESSING CB-CR CHROMINANCE INCREMENT DTO RESET SUBCARRIER INCREMENT GENERATION AND DIVIDER PHASE DEMODULATOR AMPLITUDE DETECTOR BURST GATE ACCUMULATOR LOOP FILTER CHROMA GAIN CONTROL SET_RAW SET_VBI PAL DELAY LINE CB-CR ADJUSTMENT SECAM RECOMBINATION CDTO INCS CSTD [ 2:0] RTCO FCTC ACGC CGAIN [ 6:0] IDEL [ 3:0] CODE SECS SET_RAW SET_VBI DCVF Product specification MHB729 fH /2 switch signal SAF7118 SAF7118 Fig.11 Chrominance and luminance processing. Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.1.2.1 Chrominance path SAF7118 The 9-bit CVBS or chrominance input signal is fed to the input of a quadrature demodulator, where it is multiplied by two time-multiplexed subcarrier signals from the subcarrier generation block 1 (0 and 90 phase relationship to the demodulator axis). The frequency is dependent on the chosen colour standard. The time-multiplexed output signals of the multipliers are low-pass filtered (low-pass 1). Eight characteristics are programmable via LCWB3 to LCWB0 to achieve the desired bandwidth for the colour difference signals (PAL, NTSC) or the 0 and 90 FM signals (SECAM). The chrominance low-pass 1 characteristic also influences the grade of cross-luminance reduction during horizontal colour transients (large chrominance bandwidth means strong suppression of cross-luminance). If the Y-comb filter is disabled by YCOMB = 0 the filter influences directly the width of the chrominance notch within the luminance path (a large chrominance bandwidth means wide chrominance notch resulting in a lower luminance bandwidth). The low-pass filtered signals are fed to the adaptive comb filter block. The chrominance components are separated from the luminance via a two-line vertical stage (four lines for PAL standards) and a decision logic between the filtered and the non-filtered output signals. This block is bypassed for SECAM signals. The comb filter logic can be enabled independently for the succeeding luminance and chrominance processing by YCOMB (subaddress 09H, bit D6) and/or CCOMB (subaddress 0EH, bit D0). It is always bypassed during VBI or raw data lines programmable by the LCRn registers (subaddresses 41H to 57H); see Section 8.3. The separated CB-CR components are further processed by a second filter stage (low-pass 2) to modify the chrominance bandwidth without influencing the luminance path. Its characteristic is controlled by CHBW (subaddress 10H, bit D3). For the complete transfer characteristic of low-passes 1 and 2 see Figs 12 and 13. The SECAM processing (bypassed for QAM standards) contains the following blocks: * Baseband `bell' filters to reconstruct the amplitude and phase equalized 0 and 90 FM signals * Phase demodulator and differentiator (FM-demodulation) * De-emphasis filter to compensate the pre-emphasized input signal, including frequency offset compensation (DB or DR white carrier values are subtracted from the signal, controlled by the SECAM switch signal). 2004 Jul 22 25 The succeeding chrominance gain control block amplifies or attenuates the CB-CR signal according to the required ITU 601/656 levels. It is controlled by the output signal from the amplitude detection circuit within the burst processing block. The burst processing block provides the feedback loop of the chrominance PLL and contains the following: * Burst gate accumulator * Colour identification and colour killer * Comparison nominal/actual burst amplitude (PAL/NTSC standards only) * Loop filter chrominance gain control (PAL/NTSC standards only) * Loop filter chrominance PLL (only active for PAL/NTSC standards) * PAL/SECAM sequence detection, H/2-switch generation. The increment generation circuit produces the Discrete Time Oscillator (DTO) increment for both subcarrier generation blocks. It contains a division by the increment of the line-locked clock generator to create a stable phase-locked sine signal under all conditions (e.g. for non-standard signals). The PAL delay line block eliminates crosstalk between the chrominance channels in accordance with the PAL standard requirements. For NTSC colour standards the delay line can be used as an additional vertical filter. If desired, it can be switched off by DCVF = 1. It is always disabled during VBI or raw data lines programmable by the LCRn registers (subaddresses 41H to 57H); see Section 8.3. The embedded line delay is also used for SECAM recombination (cross-over switches). Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 (1) (2) (3) (4) LCBW[2:0] = 000. LCBW[2:0] = 010. LCBW[2:0] = 100. LCBW[2:0] = 110. -48 -51 -54 -57 -60 0 (1) (2) (3) (4) MHB533 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 f (MHz) 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 (5) LCBW[2:0] = 001. (6) LCBW[2:0] = 011. (7) LCBW[2:0] = 101. (8) LCBW[2:0] = 111. -48 -51 -54 -57 -60 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 f (MHz) (5) (6) (7) (8) Fig.12 Transfer characteristics of the chrominance low-pass at CHBW = 0. 2004 Jul 22 26 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 (1) (2) (3) (4) LCBW[2:0] = 000. LCBW[2:0] = 010. LCBW[2:0] = 100. LCBW[2:0] = 110. -48 -51 -54 -57 -60 0 (1) (2) (3) (4) MHB534 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 f (MHz) 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 (5) LCBW[2:0] = 001. (6) LCBW[2:0] = 011. (7) LCBW[2:0] = 101. (8) LCBW[2:0] = 111. -48 -51 -54 -57 -60 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 f (MHz) (5) (6) (7) (8) Fig.13 Transfer characteristics of the chrominance low-pass at CHBW = 1. 2004 Jul 22 27 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.1.2.2 Luminance path SAF7118 The rejection of the chrominance components within the 9-bit CVBS or Y input signal is achieved by subtracting the remodulated chrominance signal from the CVBS input. The comb filtered CB-CR components are interpolated (upsampled) by the low-pass 3 block. Its characteristic is controlled by LUBW (subaddress 09H, bit D4) to modify the width of the chrominance `notch' without influencing the chrominance path. The programmable frequency characteristics available, in conjunction with the LCBW2 to LCBW0 settings, can be seen in Figs 14 to 17. It should be noted that these frequency curves are only valid for Y-comb disabled filter mode (YCOMB = 0). In comb filter mode the frequency response is flat. The centre frequency of the notch is automatically adapted to the chosen colour standard. The interpolated CB-CR samples are multiplied by two time-multiplexed subcarrier signals from the subcarrier generation block 2. This second DTO is locked to the first subcarrier generator by an increment delay circuit matched to the processing delay, which is different for PAL and NTSC standards according to the chosen comb filter algorithm. The two modulated signals are finally added to build the remodulated chrominance signal. The frequency characteristic of the separated luminance signal can be further modified by the succeeding luminance filter block. It can be configured as peaking (resolution enhancement) or low-pass block by LUFI3 to LUFI0 (subaddress 09H, bits D3 to D0). The 16 resulting frequency characteristics can be seen in Fig.18. The LUFI3 to LUFI0 settings can be used as a user programmable sharpness control. The luminance filter block also contains the adjustable Y-delay part; programmable by YDEL2 to YDEL0 (subaddress 11H, bits D2 to D0). 2004 Jul 22 28 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (1) (2) (3) (4) LCBW[2:0] = 000. LCBW[2:0] = 010. LCBW[2:0] = 100. LCBW[2:0] = 110. -51 -54 -57 -60 (1) (2) (3) (4) MHB535 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (5) LCBW[2:0] = 001. (6) LCBW[2:0] = 011. (7) LCBW[2:0] = 101. (8) LCBW[2:0] = 111. -51 -54 -57 -60 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) (5) (6) (7) (8) Fig.14 Transfer characteristics of the luminance notch filter in 3.58 MHz mode (Y-comb filter disabled) at LUBW = 0. 2004 Jul 22 29 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (1) (2) (3) (4) LCBW[2:0] = 000 LCBW[2:0] = 010 LCBW[2:0] = 100 LCBW[2:0] = 110 -51 -54 -57 -60 (1) (2) (3) (4) MHB536 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (5) LCBW[2:0] = 001 (6) LCBW[2:0] = 011 (7) LCBW[2:0] = 101 (8) LCBW[2:0] = 111 -51 -54 -57 -60 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) (5) (6) (7) (8) Fig.15 Transfer characteristics of the luminance notch filter in 3.58 MHz mode (Y-comb filter disabled) at LUBW = 1. 2004 Jul 22 30 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (1) (2) (3) (4) LCBW[2:0] = 000. LCBW[2:0] = 010. LCBW[2:0] = 100. LCBW[2:0] = 110. -51 -54 -57 -60 (1) (2) (3) (4) MHB537 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (5) LCBW[2:0] = 001. (6) LCBW[2:0] = 011. (7) LCBW[2:0] = 101. (8) LCBW[2:0] = 111. -51 -54 -57 -60 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) (5) (6) (7) (8) Fig.16 Transfer characteristics of the luminance notch filter in 4.43 MHz mode (Y-comb filter disabled) at LUBW = 0. 2004 Jul 22 31 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (1) (2) (3) (4) LCBW[2:0] = 000. LCBW[2:0] = 010. LCBW[2:0] = 100. LCBW[2:0] = 110. -51 -54 -57 -60 (1) (2) (3) (4) MHB538 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 -42 -45 -48 (5) LCBW[2:0] = 001. (6) LCBW[2:0] = 011. (7) LCBW[2:0] = 101. (8) LCBW[2:0] = 111. -51 -54 -57 -60 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 f (MHz) (5) (6) (7) (8) Fig.17 Transfer characteristics of the luminance notch filter in 4.43 MHz mode (Y-comb filter disabled) at LUBW = 1. 2004 Jul 22 32 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 MHB539 9 V (dB) 8 (1) (2) 7 6 5 4 3 (1) (2) (3) (4) (5) (6) (7) (8) LUFI[3:0] = 0001. LUFI[3:0] = 0010. LUFI[3:0] = 0011. LUFI[3:0] = 0100. LUFI[3:0] = 0101. LUFI[3:0] = 0110. LUFI[3:0] = 0111. LUFI[3:0] = 0000. 2 1 0 -1 0 3 V (dB) 0 -3 -6 -9 -12 -15 -18 -21 (9) LUFI[3:0] = 1000. (10) LUFI[3:0] = 1001. (11) LUFI[3:0] = 1010. (12) LUFI[3:0] = 1011. (13) LUFI[3:0] = 1100. (14) LUFI[3:0] = 1101. (15) LUFI[3:0] = 1110. (16) LUFI[3:0] = 1111. -24 -27 -30 -33 -36 -39 0 0.5 1.0 0.5 1.0 (3) (4) (5) (6) (7) (8) 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 f (MHz) 6.0 (9) (10) (11) (12) (13) (14) (15) (16) 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 f (MHz) 6.0 Fig.18 Transfer characteristics of the luminance peaking/low-pass filter (sharpness). 2004 Jul 22 33 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.1.2.3 Brightness Contrast Saturation (BCS) control and decoder output levels SAF7118 The resulting Y (CVBS) and CB-CR signals are fed to the BCS block, which contains the following functions: * Chrominance saturation control by DSAT7 to DSAT0 * Luminance contrast and brightness control by DCON7 to DCON0 and DBRI7 to DBRI0 * Raw data (CVBS) gain and offset adjustment by RAWG7 to RAWG0 and RAWO7 to RAWO0 * Limiting Y-CB-CR or CVBS to the values 1 (minimum) and 254 (maximum) to fulfil "ITU Recommendation 601/656". +255 handbook, full pagewidth +235 white +255 +240 +212 blue 100% blue 75% +255 +240 +212 red 100% red 75% +128 LUMINANCE 100% +128 colourless CB-COMPONENT +128 colourless CR-COMPONENT +44 +16 0 black +16 0 yellow 75% yellow 100% +44 +16 0 cyan 75% cyan 100% MHB730 a. Y output range. b. CB output range. c. CR output range. "ITU Recommendation 601/656" digital levels with default BCS (decoder) settings DCON[7:0] = 44H, DBRI[7:0] = 80H and DSAT[7:0] = 40H. Equations for modification to the Y-CB-CR levels via BCS control I2C-bus bytes DBRI, DCON and DSAT. Luminance: DCON Y OUT = Int ---------------- x ( Y - 128 ) + DBRI 68 DSAT Chrominance: ( C R C B ) OUT = Int --------------- x ( C R, C B - 128 ) + 128 64 It should be noted that the resulting levels are limited to 1 to 254 in accordance with "ITU Recommendation 601/656". Fig.19 Y-CB-CR range for scaler input and X port output. 2004 Jul 22 34 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 +255 +209 white +255 +199 white LUMINANCE LUMINANCE +71 +60 SYNC 1 black black shoulder +60 SYNC black shoulder = black sync bottom 1 sync bottom MGD700 a. Sources containing 7.5 IRE black level offset (e.g. NTSC M). b. Sources not containing black level offset. CVBS levels with default settings RAWG[7:0] = 64 and RAWO[7:0] = 128. Equation for modification of the raw data levels via bytes RAWG and RAWO: RAWG CVBS OUT = Int ----------------- x ( CVBS nom - 128 ) + RAWO 64 It should be noted that the resulting levels are limited to 1 to 254 in accordance with "ITU Recommendation 601/656". Fig.20 CVBS (raw data) range for scaler input, data slicer and X port output. 8.1.3 SYNCHRONIZATION The prefiltered luminance signal is fed to the synchronization stage. Its bandwidth is further reduced to 1 MHz in a low-pass filter. The sync pulses are sliced and fed to the phase detectors where they are compared with the sub-divided clock frequency. The resulting output signal is applied to the loop filter to accumulate all phase deviations. Internal signals (e.g. HCL and HSY) are generated in accordance with analog front-end requirements. The loop filter signal drives an oscillator to generate the line frequency control signal LFCO; see Fig.21. The detection of `pseudo syncs' as part of the Macrovision copy protection standard is also achieved within the synchronization circuit. The result is reported as flag COPRO within the decoder status byte at subaddress 1FH. 2004 Jul 22 35 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.1.4 CLOCK GENERATION CIRCUIT Table 3 Decoder clock frequencies CLOCK XTALO LLC LLC2 LLC4 (internal) LLC8 (virtual) SAF7118 The internal CGC generates all clock signals required for the video input processor. The internal signal LFCO is a digital-to-analog converted signal provided by the horizontal PLL. It is the multiple of the line frequency: 6.75 MHz = 429 x fH (50 Hz), or 6.75 MHz = 432 x fH (60 Hz). The LFCO signal is multiplied by a factor of 2 and 4 in the internal PLL circuit (including phase detector, loop filtering, VCO and frequency divider) to obtain the output clock signals. The rectangular output clocks have a 50% duty factor. FREQUENCY (MHz) 24.576 or 32.110 27 13.5 6.75 3.375 LFCO BAND PASS FC = LLC/4 ZERO CROSS DETECTION PHASE DETECTION LOOP FILTER OSCILLATOR LLC DIVIDER 1/2 DIVIDER 1/2 MHB330 LLC2 Fig.21 Block diagram of the clock generation circuit. 8.1.5 POWER-ON RESET AND CHIP ENABLE (CE) INPUT A missing clock, insufficient digital or analog VDDA0 supply voltages (below 2.8 V) will start the reset sequence; all outputs are forced to 3-state (see Fig.22). The indicator output RES is LOW for approximately 128 LLC after the internal reset and can be applied to reset other circuits of the digital TV system. It is possible to force a reset by pulling the Chip Enable pin (CE) to ground. After the rising edge of CE and sufficient power supply voltage, the outputs LLC, LLC2 and SDA return from 3-state to active, while the other signals have to be activated via programming. 2004 Jul 22 36 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 POC VDDA ANALOG POC VDDD DIGITAL CLOCK PLL LLC CE POC LOGIC RESINT CLK0 POC DELAY RES CE XTALO LLCINT RESINT LLC RES (internal reset) some ms 20 to 200 s PLL-delay <1 ms 896 LCC digital delay 128 LCC MHB331 POC = Power-on control. CE = chip enable input. XTALO = crystal oscillator output. LLCINT = internal system clock. RESINT = internal reset. LLC = line-locked clock output. RES = reset output. Fig.22 Power-on control circuit. 2004 Jul 22 37 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.2 Component video processing SAF7118 handbook, full pagewidth FSW FSW DELAY G/Y B/CB R/CR Y RGB/Y-CB-CR CB MATRIX CR DOWN FOMATTER and Y BCS and CB-CR COMPONENT DELAY MIXER Y to X-port CB-CR bypass BCS Y-CB-CR decoder MHB731 Fig.23 Component video processing. 8.2.1 RGB-TO-(Y-CB-CR) MATRIX The matrix converts the RGB signals from the analog-to-digital converters/downsamplers to the Y-CB-CR representation. The input and output word widths are 9 bits. The matrix has a gain factor of 1. The block provides a delay compensated bypass for component input signals. The matrix is represented by the following equations: Y = 0.299 x R + 0.587 x G + 0.114 x B CB = 0.5772 x (B - Y) CR = 0.7296 x (R - Y) 2004 Jul 22 38 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.2.2 DOWNFORMATTER SAF7118 The block mainly consists of 2 parts: the colour difference signal downsampler and the Y-path. The colour difference signals are first passed through low-pass filters which reduce alias effects due to the lower data rate. The ITU sampling scheme requires that both colour difference samples fit to the first Y sample of the current time slot. Thus the CR signal is delayed by 1 clock before it is fed to the multiplexer. The switch signal defines the data multiplex phase at the output: a `0' marks the first clock of a time slot, this is a CB sample. The output is fed through a register, so that the multiplexer runs with the opposite phase. The delay compensation for the Y signal already provides most of the registers required for a small high-pass filter. It can be used to compensate high frequency losses in the analog part. It provides 2 dB gain at 6.75 MHz. The Y high-pass filter frequency response is shown in Fig.26. The DC gain of the filter is 1, so a limiter is required at the filter output. The current implementation clips at the maximum values of 0 and 511. The entire filter can be controlled by the I2C-bus bit CMFI in subaddress 29H. handbook, full pagewidth LOW-PASS CR D Q 0 D 1 LOW-PASS CB Q (CR-CB)OUT switch delay compensation HIGH-PASS Y D n Q YOUT bypass CMFI MHB732 Fig.24 Downformatter block diagram. 2004 Jul 22 39 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 MHB788 handbook, halfpage 4 Z (dB) 3 2 1 0 -1 0 2 4 6 f (MHz) 8 Fig.25 CB-CR low-pass filter frequency response. MHB787 handbook, halfpage 2 Z (dB) 0 -20 -40 -60 0 2 4 6 f (MHz) 8 Fig.26 Y high-pass filter frequency response. 2004 Jul 22 40 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.2.3 COMPONENT VIDEO BCS CONTROL SAF7118 The resulting Y and CB-CR signals are fed to the Component BCS (CBCS) block, which contains the following functions: * Chrominance saturation control by CSAT7 to CSAT0 * Luminance contrast and brightness control by CCON7 to CCON0 and CBRI7 to CBRI0 * Limiting Y-CB-CR or CVBS to the values 1 (minimum) and 254 (maximum) to fulfil "ITU Recommendation 601/656". +255 handbook, full pagewidth +235 white +255 +240 +212 blue 100% blue 75% +255 +240 +212 red 100% red 75% +128 LUMINANCE 100% +128 colourless CB-COMPONENT +128 colourless CR-COMPONENT +44 +16 0 black +16 0 yellow 75% yellow 100% +44 +16 0 cyan 75% cyan 100% MHB730 a. Y output range. b. CB output range. c. CR output range. "ITU Recommendation 601/656" digital levels with default CBCS (decoder) settings CCON[7:0] = 44H, CBRI[7:0] = 80H and CSAT[7:0] = 40H. Equations for modification to the Y-CB-CR levels via CBCS control I2C-bus bytes CBRI, CCON and CSAT. Luminance: CCON Y OUT = Int ---------------- x ( Y - 128 ) + CBRI 68 CSAT Chrominance: ( C B C R ) OUT = Int --------------- x ( C B, C R - 128 ) + 128 64 It should be noted that the resulting levels are limited to 1 to 254 in accordance with "ITU Recommendation 601/656". Fig.27 Components Y-CB-CR range. 2004 Jul 22 41 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.3 Decoder output formatter SAF7118 The output interface block of the decoder part contains the ITU 656 formatter for the expansion port data output XPD7 to XPD0 (for a detailed description see Section 9.5.1) and the control circuit for the signals needed for the internal paths to the scaler and data slicer part. It also controls the selection of the reference signals for the RT port (RTCO, RTS0 and RTS1) and the expansion port (XRH, XRV and XDQ). The generation of the decoder data type control signals SET_RAW and SET VBI is also done within this block. These signals are decoded from the requested data type for the scaler input and/or the data slicer, selectable by the control registers LCR2 to LCR24 (see also Chapter 15; subaddresses 41H to 57H). Table 4 Data formats at decoder output DATA TYPE NUMBER 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 For each LCR value from 2 to 23 the data type can be programmed individually; LCR2 to LCR23 refer to line numbers. The selection in LCR24 values is valid for the rest of the corresponding field. The upper nibble contains the value for field 1 (odd), the lower nibble for field 2 (even). The relationship between LCR values and line numbers can be adjusted via VOFF8 to VOFF0, located in subaddresses 5BH (bit D4) and 5AH (bits D7 to D0) and FOFF subaddress 5BH (bit D7). The recommended values are VOFF[8:0] = 03H for 50 Hz sources (with FOFF = 0) and VOFF[8:0] = 06H for 60 Hz sources (with FOFF = 1), to accommodate line number conventions as used for PAL, SECAM and NTSC standards; see Tables 5 to 8. DATA TYPE teletext EuroWST, CCST European closed caption Video Programming Service (VPS) wide screen signalling bits US teletext (WST) US closed caption (line 21) video component signal, VBI region CVBS data teletext VITC/EBU time codes (Europe) VITC/SMPTE time codes (USA) reserved US NABTS MOJI (Japanese) Japanese format switch (L20/22) video component signal, active video region DECODER OUTPUT DATA FORMAT raw raw raw raw raw raw Y-CB-CR 4 : 2 : 2 raw raw raw raw raw raw raw raw Y-CB-CR 4 : 2 : 2 2004 Jul 22 42 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... Table 5 Relationship of LCR to line numbers in 525 lines/60 Hz systems (part 1) Vertical line offset, VOFF[8:0] = 06H (subaddresses 5BH[4] and 5AH[7:0]); horizontal pixel offset, HOFF[10:0] = 347H (subaddresses 5BH[2:0] and 59H[7:0]); FOFF = 1 (subaddress 5BH[7]) Line number (1st field) Line number (2nd field) LCR 521 259 522 260 523 active video 261 24 262 263 active video 524 525 1 264 2 265 2 3 266 3 4 267 4 5 serration pulses 268 5 269 6 serration pulses 6 7 270 7 8 271 8 9 272 9 equalization pulses equalization pulses equalization pulses equalization pulses 2004 Jul 22 2004 Jul 22 43 43 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input Table 6 Relationship of LCR to line numbers in 525 lines/60 Hz systems (part 2) Vertical line offset, VOFF[8:0] = 06H (subaddresses 5BH[4] and 5AH[7:0]); horizontal pixel offset, HOFF[10:0] = 347H (subaddresses 5BH[2:0] and 59H[7:0]); FOFF = 1 (subaddress 5BH[7]) Line number (1st field) Line number (2nd field) LCR 10 273 10 11 274 11 12 275 12 13 276 13 14 277 14 15 278 15 16 279 16 17 280 17 18 281 18 19 282 19 20 283 20 21 284 21 22 285 22 23 286 23 24 287 24 25 288 nominal VBI lines F1 nominal VBI lines F2 active video active video Table 7 Relationship of LCR to line numbers in 625 lines/50 Hz systems (part 1) Vertical line offset, VOFF[8:0] = 03H (subaddresses 5BH[4] and 5AH[7:0]); horizontal pixel offset, HOFF[10:0] = 347H (subaddresses 5BH[2:0] and 59H[7:0]); FOFF = 0 (subaddress 5BH[7]) Line number (1st field) Line number (2nd field) LCR 621 309 622 active video 310 311 24 active video 623 624 312 625 313 1 314 serration pulses 2 2 serration pulses 315 316 3 3 4 317 4 5 318 5 equalization pulses equalization pulses equalization pulses equalization pulses Table 8 Relationship of LCR to line numbers in 625 lines/50 Hz systems (part 2) Vertical line offset, VOFF[8:0] = 03H (subaddresses 5BH[4] and 5AH[7:0]); horizontal pixel offset, HOFF[10:0] = 347H (subaddresses 5BH[2:0] and 59H[7:0]); FOFF = 0 (subaddress 5BH[7]) Product specification Line number (1st field) Line number (2nd field) LCR 6 319 6 7 320 7 8 321 8 9 322 9 10 323 10 11 324 11 12 325 12 13 326 13 14 327 14 15 328 15 16 329 16 17 330 17 18 331 18 19 332 19 20 333 20 21 334 21 22 335 22 23 336 23 24 337 24 25 SAF7118 SAF7118 nominal VBI lines F1 nominal VBI lines F2 active video 338 active video Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 ITU counting single field counting CVBS 622 309 623 310 624 311 625 312 1 1 2 2 3 3 4 4 5 5 6 6 7 7 ... ... 22 22 23 23 HREF F_ITU656 V123 (1) VSTO [8:0] = 134H VGATE FID (a) 1st field VSTA [8:0] = 15H ITU counting single field counting CVBS 309 309 310 310 311 311 312 312 313 313 314 1 315 2 316 3 317 4 318 5 319 6 ... ... 335 22 336 23 HREF F_ITU656 V123 (1) VSTO [8:0] = 134H VGATE FID (b) 2nd field VSTA [8:0] = 15H MHB540 (1) The inactive going edge of the V123 signal indicates whether the field is odd or even. If HREF is active during the falling edge of V123, the field is ODD (field 1). If HREF is inactive during the falling edge of V123, the field is EVEN. The specific position of the slope is dependent on the internal processing delay and may change a few clock cycles from version to version. The control signals listed above are available on pins RTS0, RTS1, XRH and XRV according to the following table: NAME HREF F_ITU656 V123 VGATE FID RTS0 X - X X X RTS1 X - X X X XRH X - - - - XRV - X X - - For further information see Section 15.2: Tables 57, 58 and 59. Fig.28 Vertical timing diagram for 50 Hz/625 line systems. 2004 Jul 22 44 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 ITU counting single field counting CVBS 525 262 1 1 2 2 3 3 4 4 5 5 6 6 7 7 8 8 9 9 10 10 ... ... 21 21 22 22 HREF F_ITU656 V123 (1) VSTO [8:0] = 101H VGATE FID (a) 1st field VSTA [8:0] = 011H ITU counting single field counting CVBS 262 262 263 263 264 1 265 2 266 3 267 4 268 5 269 6 270 7 271 8 272 9 ... ... 284 21 285 22 HREF F_ITU656 V123 (1) VSTO [8:0] = 101H VGATE FID (b) 2nd field VSTA [8:0] = 011H MHB541 (1) The inactive going edge of the V123 signal indicates whether the field is odd or even. If HREF is active during the falling edge of V123, the field is ODD (field 1). If HREF is inactive during the falling edge of V123, the field is EVEN. The specific position of the slope is dependent on the internal processing delay and may change a few clock cycles from version to version. The control signals listed above are available on pins RTS0, RTS1, XRH and XRV according to the following table: NAME HREF F_ITU656 V123 VGATE FID RTS0 X - X X X RTS1 X - X X X XRH X - - - - XRV - X X - - For further information see Section 15.2: Tables 57, 58 and 59. Fig.29 Vertical timing diagram for 60 Hz/525 line systems. 2004 Jul 22 45 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 CVBS input burst processing delay ADC to expansion port: 140 x 1/LLC expansion port data output sync clipped HREF (50 Hz) 720 x 2/LLC CREF CREF2 5 x 2/LLC HS (50 Hz) programming range 108 (step size: 8/LLC) 0 2 x 2/LLC -107 12 x 2/LLC 144 x 2/LLC HREF (60 Hz) 16 x 2/LLC 720 x 2/LLC CREF CREF2 HS (60 Hz) programming range (step size: 8/LLC) 107 0 138 x 2/LLC 1 x 2/LLC 2 x 2/LLC -106 MHB542 The signals HREF, HS, CREF2 and CREF are available on pins RTS0 and/or RTS1 (see Section 15.2.19 Tables 57 and 58); their polarity can be inverted via RTP0 and/or RTP1. The signals HREF and HS are available on pin XRH (see Section 15.2.20 Table 59). Fig.30 Horizontal timing diagram (50/60 Hz). 2004 Jul 22 46 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.4 Scaler SAF7118 The High Performance video Scaler (HPS) is based on the system as implemented in previous products, but with some aspects enhanced. Vertical upsampling is supported and the processing pipeline buffer capacity is enhanced, to allow more flexible video stream timing at the image port, discontinuous transfers, and handshake. The internal data flow from block to block is discontinuous dynamically, due to the scaling process. The flow is controlled by internal data valid and data request flags (internal handshake signalling) between the sub-blocks; therefore the entire scaler acts as a pipeline buffer. Depending on the actually programmed scaling parameters the effective buffer can exceed to an entire line. The access/bandwidth requirements to the VGA frame buffer are reduced significantly. The high performance video scaler in the SAF7118 has the following major blocks: * Acquisition control (horizontal and vertical timer) and task handling (the region/field/frame based processing) * Prescaler, for horizontal downscaling by an integer factor, combined with appropriate band limiting filters, especially anti-aliasing for CIF format * Brightness, saturation, contrast control for scaled output data * Line buffer, with asynchronous read and write, to support vertical upscaling (e.g. for videophone application, converting 240 into 288 lines, Y-CB-CR 4 : 2 : 2) * Vertical scaling, with phase accurate Linear Phase Interpolation (LPI) for zoom and downscale, or phase accurate Accumulation Mode (ACM) for large downscaling ratios and better alias suppression * Variable Phase Delay (VPD), operates as horizontal phase accurate interpolation for arbitrary non-integer scaling ratios, supporting conversion between square and rectangular pixel sampling * Output formatter for scaled Y-CB-CR 4 : 2 : 2, Y-CB-CR 4 : 1 : 1 and Y only (format also used for raw data) * FIFO, 32-bit wide, with 64 pixel capacity in Y-CB-CR formats * Output interface, 8 or 16-bit (only if extended by H port) data pins wide, synchronous or asynchronous operation, with stream events on discrete pins, or coded in the data stream. The overall H and V zooming (HV_zoom) is restricted by the input/output data rate relationships. With a safety margin of 2% for running in and running out, the maximum HV_zoom is equal to: T_input_field - T_v_blanking 0.98 x ------------------------------------------------------------------------------------------------------------------------------------in_pixel x in_lines x out_cycle_per_pix x T_out_clk For example: 1. Input from decoder: 50 Hz, 720 pixel, 288 lines, 16-bit data at 13.5 MHz data rate, 1 cycle per pixel; output: 8-bit data at 27 MHz, 2 cycles per pixel; the maximum HV_zoom is equal to: 20 ms - 24 x 64 s 0.98 x -------------------------------------------------------- = 1.18 720 x 288 x 2 x 37 ns 2. Input from X port: 60 Hz, 720 pixel, 240 lines, 8-bit data at 27 MHz data rate (ITU 656), 2 cycles per pixel; output via I + H port: 16-bit data at 27 MHz clock, 1 cycle per pixel; the maximum HV_zoom is equal to: 16.666 ms - 22 x 64 s 0.98 x ------------------------------------------------------------- = 2.34 720 x 240 x 1 x 37 ns The video scaler receives its input signal from the video decoder or from the expansion port (X port). It gets 16-bit Y-CB-CR 4 : 2 : 2 input data at a continuous rate of 13.5 MHz from the decoder. Discontinuous data stream can be accepted from the expansion port (X port), normally 8-bit wide ITU 656 such as Y-CB-CR data, accompanied by a pixel qualifier on XDQ. The input data stream is sorted into two data paths, one for luminance (or raw samples) and one for time multiplexed chrominance CB and CR samples. An Y-CB-CR 4 : 1 : 1 input format is converted to 4 : 2 : 2 for the horizontal prescaling and vertical filter scaling operation. The scaler operation is defined by two programming pages A and B, representing two different tasks, that can be applied field alternating or to define two regions in a field (e.g. with different scaling range, factors and signal source during odd and even fields). Each programming page contains control: * For signal source selection and formats * For task handling and trigger conditions * For input and output acquisition window definition * For H-prescaler, V-scaler and H-phase scaling. Raw VBI data is handled as a specific input format and needs its own programming page (equals own task). 2004 Jul 22 47 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input In VBI pass through operation the processing of prescaler and vertical scaling has to be set to no-processing, however, the horizontal fine scaling VPD can be activated. Upscaling (oversampling, zooming), free of frequency folding, up to a factor of 3.5 can be achieved, as required by some software data slicing algorithms. These raw samples are transported through the image port as valid data and can be output as Y only format. The lines are framed by SAV and EAV codes. 8.4.1 ACQUISITION CONTROL AND TASK HANDLING (SUBADDRESSES 80H, 90H, 91H, 94H TO 9FH AND C4H TO CFH) 8.4.1.1 Input field processing SAF7118 The trigger event for the field sequence detection from external signals (X port) are defined in subaddress 92H. From the X port the state of the scalers H reference signal at the time of the V reference edge is taken as field sequence identifier FID. For example, if the falling edge of the XRV input signal is the reference and the state of XRH input is logic 0 at that time, the detected field ID is logic 0. The bits XFDV[92H[7]] and XFDH[92H[6]] define the detection event and state of the flag from the X port. For the default setting of XFDV and XFDH at `00' the state of the H-input at the falling edge of the V-input is taken. The scaler directly gets a corresponding field ID information from the SAF7118 decoder path. The FID flag is used to determine whether the first or second field of a frame is going to be processed within the scaler and it is used as trigger condition for the task handling (see bits STRC[1:0] 90H[1:0]). According to ITU 656, when FID is at logic 0 means first field of a frame. To ease the application, the polarities of the detection results on the X port signals and the internal decoder ID can be changed via XFDH. As the V-sync from the decoder path has a half line timing (due to the interlaced video signal), but the scaler processing only knows about full lines, during 1st fields from the decoder the line count of the scaler possibly shifts by one line, compared to the 2nd field. This can be compensated for by switching the V-trigger event, as defined by XDV0, to the opposite V-sync edge or by using the vertical scalers phase offsets. The vertical timing of the decoder can be seen in Figs 28 and 29. As the H and V reference events inside the ITU 656 data stream (from X port) and the real-time reference signals from the decoder path are processed differently, the trigger events for the input acquisition also have to be programmed differently. The acquisition control receives horizontal and vertical synchronization signals from the decoder section or from the X port. The acquisition window is generated via pixel and line counters at the appropriate places in the data path. From X port only qualified pixels and lines (lines with qualified pixel) are counted. The acquisition window parameters are as follows: * Signal source selection regarding input video stream and formats from the decoder, or from X port (programming bits SCSRC[1:0] 91H[5:4] and FSC[2:0] 91H[2:0]) Remark: The input of raw VBI data from the internal decoder should be controlled via the decoder output formatter and the LCR registers; see Section 8.3 * Vertical offset defined in lines of the video source, parameter YO[11:0] 99H[3:0] 98H[7:0] * Vertical length defined in lines of the video source, parameter YS[11:0] 9BH[3:0] 9AH[7:0] * Vertical length defined in number of target lines, as a result of vertical scaling, parameter YD[11:0] 9FH[3:0] 9EH[7:0] * Horizontal offset defined in number of pixels of the video source, parameter XO[11:0] 95H[3:0] 94H[7:0] * Horizontal length defined in number of pixels of the video source, parameter XS[11:0] 97H[3:0] 96H[7:0] * Horizontal destination size, defined in target pixels after fine scaling, parameter XD[11:0] 9DH[3:0] 9CH[7:0]. The source start offset (XO11 to XO0 and YO11 to YO0) opens the acquisition window, and the target size (XD11 to XD0 and YD11 to YD0) closes the window, however the window is cut vertically if there are less output lines than expected. The trigger events for the pixel and line counts are the horizontal and vertical reference edges as defined in subaddress 92H. The task handling is controlled by subaddress 90H; see Section 8.4.1.2. 2004 Jul 22 48 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 9 XDV1 92H[5] Processing trigger and start XDV0 92H[4] XDH 92H[2] DESCRIPTION SAF7118 Internal decoder: The processing triggers at the falling edge of the V123 pulse [see Figs 28 (50 Hz) and 29 (60 Hz)], and starts earliest with the rising edge of the decoder HREF at line number: 0 0 0 1 0 0 0 0 0 4/7 (50/60 Hz, 1st field), respectively 3/6 (50/60 Hz, 2nd field) (decoder count) 2/5 (50/60 Hz, 1st field), respectively 2/5 (50/60 Hz, 2nd field) (decoder count) External ITU 656 stream: The processing starts earliest with SAV at line number 23 (50 Hz system), respectively line 20 (60 Hz system) (according to ITU 656 count) Remarks: * To activate a task the start condition must be fulfilled and the acquisition window offsets must be reached. For example, in case of `start immediately', and two regions are defined for one field, the offset of the lower region must be greater than (offset + length) of the upper region, if not, the actual counted H and V position at the end of the upper task is beyond the programmed offsets and the processing will `wait for next V'. * Basically the trigger conditions are checked, when a task is activated. It is important to realize, that they are not checked while a task is inactive. So you can not trigger to next logic 0 or logic 1 with overlapping offset and active video ranges between the tasks (e.g. task A STRC[2:0] = 2, YO[11:0] = 310 and task B STRC[2:0] = 3, YO[11:0] = 310 results in output field rate of 503 Hz). * After power-on or software reset (via SWRST[88H[5]]) task B gets priority over task A. 8.4.1.3 Output field processing 8.4.1.2 Task handling The task handler controls the switching between the two programming register sets. It is controlled by subaddresses 90H and C0H. A task is enabled via the global control bits TEA[80H[4]] and TEB[80H[5]]. The handler is then triggered by events, which can be defined for each register set. In the event of a programming error the task handling and the complete scaler can be reset to the initial states by setting the software reset bit SWRST[88H[5]] to logic 0. Especially if the programming registers, related acquisition window and scale are reprogrammed while a task is active, a software reset must be performed after programming. Contrary to the disabling/enabling of a task, which is evaluated at the end of a running task, when SWRST is at logic 0 it sets the internal state machines directly to their idle states. The start condition for the handler is defined by bits STRC[1:0] 90H[1:0] and means: start immediately, wait for next V-sync, next FID at logic 0 or next FID at logic 1. The FID is evaluated, if the vertical and horizontal offsets are reached. When RPTSK[90H[2]] is at logic 1 the actual running task is repeated (under the defined trigger conditions), before handing control over to the alternate task. To support field rate reduction, the handler is also enabled to skip fields (bits FSKP[2:0] 90H[5:3]) before executing the task. A TOGGLE flag is generated (used for the correct output field processing), which changes state at the beginning of a task, every time a task is activated; examples are given in Section 8.4.1.3. As a reference for the output field processing, two signals are available for the back-end hardware. These signals are the input field ID from the scaler source and a TOGGLE flag, which shows that an active task is used an odd (1, 3, 5...) or even (2, 4, 6...) number of times. Using a single or both tasks and reducing the field or frame rate with the task handling function, the TOGGLE information can be used to reconstruct an interlaced scaled picture at a reduced frame rate. The TOGGLE flag isn't synchronized to the input field detection, as it is only dependent on the interpretation of this information by the external hardware, whether the output of the scaler is processed correctly; see Section 8.4.3. 2004 Jul 22 49 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... With OFIDC = 0, the scalers input field ID is available as output field ID on bit D6 of SAV and EAV, respectively on pin IGP0 (IGP1), if FID output is selected. When OFIDC[90H[6]] = 1, the TOGGLE information is available as output field ID on bit D6 of SAV and EAV, respectively on pin IGP0 (IGP1), if FID output is selected. Additionally the bit D7 of SAV and EAV can be defined via CONLH[90H[7]]. CONLH[90H[7]] = 0 (default) sets D7 to logic 1, a logic 1 inverts the SAV/EAV bit D7. So it is possible to mark the output of the both tasks by different SAV/EAV codes. This bit can also be seen as `task flag' on the pins IGP0 (IGP1), if TASK output is selected. Table 10 Examples for field processing FIELD SEQUENCE FRAME/FIELD SUBJECT EXAMPLE 1(1) 1/1 Processed by task State of detected ITU 656 FID TOGGLE flag Bit D6 of SAV/EAV byte 50 50 Required sequence conversion at the vertical scaler(8) Output(9) Notes 1. Single task every field; OFIDC = 0; subaddress 90H at 40H; TEB[80H[5]] = 0. 2. Tasks are used to scale to different output windows, priority on task B after SWRST. 3. Both tasks at 12 frame rate; OFIDC = 0; subaddresses 90H at 43H and C0H at 42H. 4. In examples 3 and 4 the association between input FID and tasks can be flipped, dependent on which time the SWRST is de-asserted. 5. Task B at 23 frame rate constructed from neighbouring motion phases; task A at 13 frame rate of equidistant motion phases; OFIDC = 1; subaddresses 90H at 41H and C0H at 45H. 6. Task A and B at 13 frame rate of equidistant motion phases; OFIDC = 1; subaddresses 90H at 41H and C0H at 49H. 7. State of prior field. 8. It is assumed that input/output FID = 0 (= upper lines); UP = upper lines; LO = lower lines. 9. O = data output; NO = no output. Product specification A 0 1 0 UP UP O 1/2 A 1 0 1 LO LO O 2/1 A 0 1 0 UP UP O EXAMPLE 2(2)(3) 1/1 B 0 1 0 UP UP O 1/2 A 1 1 1 LO LO O 2/1 B 0 0 0 UP UP O 2/2 A 1 0 1 LO LO O 1/1 B 0 1 1 UP LO O EXAMPLE 3(2)(4)(5) 1/2 B 1 0 0 LO UP O 2/1 A 0 1 1 UP LO O 2/2 B 1 1 1 LO LO O 3/1 B 0 0 0 UP UP O 3/2 A 1 0 0 LO UP O 1/1 B 0 0(7) 0(7) UP UP NO EXAMPLE 4(2)(4)(6) 1/2 B 1 1 1 LO LO O 2/1 A 0 1 1 UP LO O 2/2 B 1 1(7) 1(7) LO LO NO 3/1 B 0 0 0 UP UP O 3/2 A 1 0 0 LO UP O 2004 Jul 22 2004 Jul 22 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input SAF7118 SAF7118 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.4.2 HORIZONTAL SCALING SAF7118 The overall horizontal required scaling factor has to be split into a binary and a rational value according to the equation: output pixel H-scale ratio = ----------------------------input pixel 1 1024 H-scale ratio = --------------------------- x -----------------------------XPSC[5:0] XSCY[12:0] where the parameter of prescaler XPSC[5:0] = 1 to 63 and the parameter of VPD phase interpolation XSCY[12:0] = 300 to 8191 (0 to 299 are only theoretical values). For example, 13.5 is to split in 14 x 1.14286. The binary factor is processed by the prescaler, the arbitrary non-integer ratio is achieved via the variable phase delay VPD circuitry, called horizontal fine scaling. The latter calculates horizontally interpolated new samples with a 6-bit phase accuracy, which relates to less than 1 ns jitter for regular sampling scheme. Prescaler and fine scaler create the horizontal scaler of the SAF7118. Using the accumulation length function of the prescaler (XACL[5:0] A1H[5:0]), application and destination dependent (e.g. scale for display or for a compression machine), a compromise between visible bandwidth and alias suppression can be determined. 8.4.2.1 Horizontal prescaler (subaddresses A0H to A7H and D0H to D7H) * The bit XC2_1[A2H[3]], which defines the weighting of the incoming pixels during the averaging process: - XC2_1 = 0 1 + 1...+ 1 +1 - XC2_1 = 1 1 + 2...+ 2 +1. The prescaler creates a prescale dependent FIR low-pass, with up to (64 + 7) filter taps. The parameter XACL[5:0] can be used to vary the low-pass characteristic for a given integer prescale of 1XPSC[5:0]. The user can therefore decide between signal bandwidth (sharpness impression) and alias. Equation for XPSC[5:0] calculation is: Npix_in XPSC[5:0] = lower integer of ---------------------Npix_out Where: the range is 1 to 63 (value 0 is not allowed); Npix_in = number of input pixel, and Npix_out = number of desired output pixel over the complete horizontal scaler. The use of the prescaler results in a XACL[5:0] and XC2_1 dependent gain amplification. The amplification can be calculated according to the equation: DC gain = (XC2_1 + 1) x XACL[5:0] + (1 - XC2_1) It is recommended to use sequence lengths and weights, which results in a 2N DC gain amplification, as these amplitudes can be renormalized by the XDCG[2:0] 1 controlled ------ shifter of the prescaler. N 2 The renormalization range of XDCG[2:0] is 1, 12 down to 1128. Other amplifications have to be normalized by using the following BCS control circuitry. In these cases the prescaler has to be set to an overall gain of 1, e.g. for an accumulation sequence of `1 + 1 + 1' (XACL[5:0] = 2 and XC2_1 = 0), XDCG[2:0] must be set to `010', this equals 14 and the BCS has to amplify the signal to 43 (SATN[7:0] and CONT[7:0] value = lower integer of 43 x 64). The use of XACL[5:0] is XPSC[5:0] dependent. XACL[5:0] must be <2 x XPSC[5:0]. XACL[5:0] can be used to find a compromise between bandwidth (sharpness) and alias effects. The prescaling function consists of an FIR anti-alias filter stage and an integer prescaler, which creates an adaptive prescale dependent low-pass filter to balance sharpness and aliasing effects. The FIR prefilter stage implements different low-pass characteristics to reduce alias for downscales in the range of 1 to 12. A CIF optimized filter is built-in, which reduces artefacts for CIF output formats (to be used in combination with the prescaler set to 12 scale); see Table 11. The function of the prescaler is defined by: * An integer prescaling ratio XPSC[5:0] A0H[5:0] (equals 1 to 63), which covers the integer downscale range 1 to 163 * An averaging sequence length XACL[5:0] A1H[5:0] (equals 0 to 63); range 1 to 64 * A DC gain renormalization XDCG[2:0] A2H[2:0]; 1 down to 1128 2004 Jul 22 51 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Remark: Due to bandwidth considerations XPSC[5:0] and XACL[5:0] can be chosen differently to the previously mentioned equations or Table 12, as the H-phase scaling is able to scale in the range from zooming up by factor 3 to downscaling by a factor of 10248191. Figures 33 and 34 show some resulting frequency characteristics of the prescaler. Table 12 shows the recommended prescaler programming. Other programmings, other than given in Table 12, may result in better alias suppression, but the resulting DC gain amplification needs to be compensated by the BCS control, according to the equation: 2 CONT[7:0] = SATN[7:0] = lower integer of --------------------------------DC gain x 64 Where: 2XDCG[2:0] DC gain DC gain = (XC2_1 + 1) x XACL[5:0] + (1 - XC2_1). Table 11 FIR prefilter functions PFUV[1:0] A2H[7:6] PFY[1:0] A2H[5:4] 00 01 10 11 LUMINANCE FILTER COEFFICIENTS bypassed 121 -1 1 1.75 4.5 1.75 1 -1 12221 XDCG[2:0] SAF7118 For example, if XACL[5:0] = 5, XC2_1 = 1, then the DC gain = 10 and the required XDCG[2:0] = 4. The horizontal source acquisition timing and the prescaling ratio is identical for both the luminance path and chrominance path, but the FIR filter settings can be defined differently in the two channels. Fade-in and fade-out of the filters is achieved by copying an original source sample each as first and last pixel after prescaling. Figures 31 and 32 show the frequency characteristics of the selectable FIR filters. CHROMINANCE COEFFICIENTS bypassed 121 3 8 10 8 3 12221 2004 Jul 22 52 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 6 V 3 (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 (1) PFY[1:0] = 01. (2) PFY[1:0] = 10. (3) PFY[1:0] = 11. -42 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 (3) (2) (1) MHB543 0.45 f_sig/f_clock 0.5 Fig.31 Luminance prefilter characteristic. 6 V 3 (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 -39 (1) PFUV[1:0] = 01. (2) PFUV[1:0] = 10. (3) PFUV[1:0] = 11. -42 0 0.025 0.05 0.075 0.1 0.125 0.15 0.175 0.2 (2) (3) (1) MHB544 0.225 0.25 f_sig/f_clock Fig.32 Chrominance prefilter characteristic. 2004 Jul 22 53 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 6 V 3 (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 -33 -36 XC2_1 = 0; Zero's at 1 f = n x -----------------------XACL + 1 with XACL = (1), (2), (3), (4) or (5) -39 -42 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 (5) (4) (3) (2) (1) MHB545 0.45 f_sig/f_clock 0.5 Fig.33 Examples for prescaler filter characteristics: effect of increasing XACL[5:0]. 6 V 3 (dB) 0 -3 -6 -9 -12 -15 -18 -21 -24 -27 -30 (1) XC2_1 = 0 and XACL[5:0] = 1. (2) XC2_1 = 1 and XACL[5:0] = 2. (3) XC2_1 = 0 and XACL[5:0] = 3. (4) XC2_1 = 1 and XACL[5:0] = 4. (5) XC2_1 = 0 and XACL[5:0] = 7. (6) XC2_1 = 1 and XACL[5:0] = 8. -33 -36 -39 -42 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 (2) (6) (5) (4) (3) MHB546 (1) 3 dB at 0.25 6 dB at 0.33 0.45 f_sig/f_clock 0.5 Fig.34 Examples for prescaler filter characteristics: setting XC2_1 = 1. 2004 Jul 22 54 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 12 XACL[5:0] example of usage RECOMMENDED VALUES PRESCALE XPSC RATIO [5:0] FOR LOWER BANDWIDTH REQUIREMENTS XACL[5:0] 1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 1 9 1 1 1 1 1 1 1 1 SAF7118 FOR HIGHER BANDWIDTH REQUIREMENTS XACL[5:0] 0 1 3 4 7 7 7 8 (1) 16 XC2_1 0 1 (1 2 1) x 1 (1) 4 XDCG[2:0] 0 2 3 1 (1) 8 XC2_1 0 0 (1 1) x 0 1 (1) 2 XDCG[2:0] 0 1 2 FIR PREFILTER PFY[1:0]/ PFUV[1:0] 0 to 2 0 to 2 2 2 2 3 3 3 3 3 3 3 3 3 3 3 3 1 2 3 4 5 6 7 8 9 10 13 15 16 19 31 32 35 0 2 4 7 8 8 8 15 15 16 16 31 32 32 32 63 63 1 (1 2 2 2 1) x 0 (1 1 1 1 1 1 1 1) x 18(1) 1 (1 2 2 2 2 2 2 2 1) x 1 (1 2 2 2 2 2 2 2 1) x 1 (1 2 2 2 2 2 2 2 1) x 116(1) 0 0 1 1 0 1 1 1 1 1 1 (1) 16 1 (1) 16 (1 1 1 1) x 3 4 4 4 4 1 1 (1) 4 1 (1 2 2 2 1) x 18(1) 0 (1 1 1 1 1 1 1 1) x 0 (1 1 1 1 1 1 1 1) x 0 (1 1 1 1 1 1 1 1) x 18(1) 1 1 1 1 1 1 1 1 1 1 1 (1) 8 1 (1) 8 3 3 3 3 4 1 (1) 16 (1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1) x (1 2 2 2 2 2 2 2 1) x 8 8 4 5 1 (1) 32 4 4 1 (1) 16 (1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1) x 116(1) 10 (1 2 2 2 2 2 2 2 1) x 116(1) (1 2 2 2 2 2 2 2 1) x 16 16 16 32 32 32 63 (1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1) x 13 15 16 19 31 32 35 5 5 6 6 6 7 7 5 5 5 6 6 6 7 Note 1. Resulting FIR function. 2004 Jul 22 55 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.4.2.2 Horizontal fine scaling (variable phase delay filter; subaddresses A8H to AFH and D8H to DFH) 8.4.3.1 SAF7118 Line FIFO buffer (subaddresses 91H, B4H and C1H, E4H) The horizontal fine scaling (VPD) should operate at scaling ratios between 12 and 2 (0.8 and 1.6), but can also be used for direct scaling in the range from 17.999 to (theoretical) zoom 3.5 (restriction due to the internal data path architecture), without prescaler. In combination with the prescaler a compromise between sharpness impression and alias can be found. This is signal source and application dependent. For the luminance channel a filter structure with 10 taps is implemented, and for the chrominance a filter with 4 taps. Luminance and chrominance scale increments (XSCY[12:0] A9H[4:0] A8H[7:0] and XSCC[12:0] ADH[4:0] ACH[7:0]) are defined independently, but must be set in a 2 : 1 relationship in the actual data path implementation. The phase offsets XPHY[7:0] AAH[7:0] and XPHC[7:0] AEH[7:0] can be used to shift the sample phases slightly. XPHY[7:0] and XPHC[7:0] covers the phase offset range 7.999T to 132T. The phase offsets should also be programmed in a 2 : 1 ratio. The underlying phase controlling DTO has a 13-bit resolution. According to the equations Npix_in 1 XSCY[12:0] = 1024 x --------------------------- x ---------------------- and XPSC[5:0] Npix_out XSCY[12:0] XSCC[12:0] = -----------------------------2 the VPD covers the scale range from 0.125 to zoom 3.5. VPD acts equivalent to a polyphase filter with 64 possible phases. In combination with the prescaler, it is possible to get very accurate samples from a highly anti-aliased integer downscaled input picture. 8.4.3 VERTICAL SCALING The line FIFO buffer is a dual ported RAM structure for 768 pixels, with asynchronous write and read access. The line buffer can be used for various functions, but not all functions may be available simultaneously. The line buffer can buffer a complete unscaled active video line or more than one shorter lines (only for non-mirror mode), for selective repetition for vertical zoom-up. For zooming up 240 lines to 288 lines e.g., every fourth line is requested (read) twice from the vertical scaling circuitry for calculation. For conversion of a 4 : 2 : 0 or 4 : 1 : 0 input sampling scheme (MPEG, video phone, Indeo YUV-9) to ITU like sampling scheme 4 : 2 : 2, the chrominance line buffer is read twice or four times, before being refilled again by the source. It has to be preserved by means of the input acquisition window definition, so that the processing starts with a line containing luminance and chrominance information for 4 : 2 : 0 and 4 : 1 : 0 input. The bits FSC[2:1] 91H[2:1] define the distance between the Y/C lines. In the event of 4 : 2 : 2 and 4 : 1 : 1 FSC2 and FSC1 have to be set to `00'. The line buffer can also be used for mirroring, i.e. for flipping the image left to right, for the vanity picture in video phone applications (bit YMIR[B4H[4]]). In mirror mode only one active prescaled line can be held in the FIFO at a time. The line buffer can be utilized as an excessive pipeline buffer for discontinuous and variable rate transfer conditions at the expansion port or image port. The vertical scaler of the SAF7118 consists of a line FIFO buffer for line repetition and the vertical scaler block, which implements the vertical scaling on the input data stream in 2 different operational modes from theoretical zoom by 64 down to icon size 164. The vertical scaler is located between the BCS and horizontal fine scaler, so that the BCS can be used to compensate the DC gain amplification of the ACM mode (see Section 8.4.3.2) as the internal RAMs are only 8-bit wide. 2004 Jul 22 56 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.4.3.2 Vertical scaler (subaddresses B0H to BFH and E0H to EFH) SAF7118 Vertical scaling of any ratio from 64 (theoretical zoom) to 163 (icon) can be applied. The vertical scaling block consists of another line delay, and the vertical filter structure, that can operate in two different modes; Linear Phase Interpolation (LPI) and accumulation (ACM) mode. These are controlled by YMODE[B4H[0]]: * LPI mode: In LPI mode (YMODE = 0) two neighbouring lines of the source video stream are added together, but weighted by factors corresponding to the vertical position (phase) of the target output line relative to the source lines. This linear interpolation has a 6-bit phase resolution, which equals 64 intra line phases. It interpolates between two consecutive input lines only. LPI mode should be applied for scaling ratios around 1 (down to 12), it must be applied for vertical zooming. * ACM mode: The vertical Accumulation (ACM) mode (YMODE = 1) represents a vertical averaging window over multiple lines, sliding over the field. This mode also generates phase correct output lines. The averaging window length corresponds to the scaling ratio, resulting in an adaptive vertical low-pass effect, to greatly reduce aliasing artefacts. ACM can be applied for downscales only from ratio 1 down to 164. ACM results in a scale dependent DC gain amplification, which has to be precorrected by the BCS control of the scaler part. The phase and scale controlling DTO calculates in 16-bit resolution, controlled by parameters YSCY[15:0] B1H[7:0] B0H[7:0] and YSCC[15:0] B3H[7:0] B2H[7:0], continuously over the entire filed. A start offset can be applied to the phase processing by means of the parameters YPY3[7:0] to YPY0[7:0] in BFH[7:0] to BCH[7:0] and YPC3[7:0] to YPC0[7:0] in BBH[7:0] to B8H[7:0]. The start phase covers the range of 25532 to 132 lines offset. By programming appropriate, opposite, vertical start phase values (subaddresses B8H to BFH and E8H to EFH) depending on odd or even field ID of the source video stream and A or B page cycle, frame ID conversion and field rate conversion are supported (i.e. de-interlacing, re-interlacing). Figures 35 and 36 and Tables 13 and 14 describe the use of the offsets. Remark: The vertical start phase, as well as scaling ratio are defined independently for the luminance and chrominance channel, but must be set to the same values in the actual implementation for accurate 4 : 2 : 2 output processing. The vertical processing communicates on its input side with the line FIFO buffer. The scale related equations are: * Scaling increment calculation for ACM and LPI mode, downscale and zoom: YSCY[15:0] and YSCC[15:0] Nline_in = lower integer of 1024 x ------------------------ Nline_out * BCS value to compensate DC gain in ACM mode (contrast and saturation have to be set): CONT[7:0] A5H[7:0] respectively SATN[7:0] A6H[7:0] Nline_out = lower integer of ------------------------ x 64 , or Nline_in 1024 = lower integer of ------------------------------ x 64 YSCY[15:0] 8.4.3.3 Use of the vertical phase offsets As described in Section 8.4.1.3, the scaler processing may run randomly over the interlaced input sequence. Additionally the interpretation and timing between ITU 656 field ID and real-time detection by means of the state of H-sync at the falling edge of V-sync may result in different field ID interpretation. A vertically scaled interlaced output also gets a larger vertical sampling phase error, if the interlaced input fields are processed, without regard to the actual scale at the starting point of operation (see Fig.35). For correct interlaced processing the vertical scaler must be used with respect to the interlace properties of the input signal and, if required, for conversion of the field sequences. Four events should be considered, they are illustrated in Fig.36. 2004 Jul 22 57 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 unscaled input field 1 field 2 scaled output, no phase offset field 1 field 2 scaled output, with phase offset field 1 field 2 correct scale dependent position scale dependent start offset mismatched vertical line distances MHB547 Fig.35 Basic problem of interlaced vertical scaling (example: downscale 35). handbook, full pagewidth field 1 upper B A field 2 lower field 1 case UP-UP field 2 case LO-LO field 1 case UP-LO field 2 case LO-UP C D MHB548 1024 Offset = ------------ = 32 = 1 line shift 32 1 A = -- input line shift = 16 2 1 1 YSCY[15:0] B = -- input line shift + -- scale increment = ------------------------------ + 16 2 2 64 1 YSCY[15:0] C = -- scale increment = -----------------------------2 64 D = no offset = 0 Fig.36 Derivation of the phase related equations (example: interlace vertical scaling down to 35, with field conversion). 2004 Jul 22 58 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input In Tables 13 and 14 PHO is a usable common phase offset. It should be noted that the equations of Fig.36 produce an interpolated output, also for the unscaled case, as the geometrical reference position for all conversions is the position of the first line of the lower field; see Table 13. If there is no need for UP-LO and LO-UP conversion and the input field ID is the reference for the back-end operation, then it is UP-LO = UP-UP and LO-UP = LO-LO and the 12 line phase shift (PHO + 16) that can be skipped. This case is listed in Table 14. The SAF7118 supports 4 phase offset registers per task and component (luminance and chrominance). The value of 20H represents a phase shift of one line. SAF7118 The registers are assigned to the following events; e.g. subaddresses B8H to BBH: * B8H: 00 = input field ID 0, task status bit D0 (toggle status; see Section 8.4.1.3) * B9H: 01 = input field ID 0, task status bit D1 * BAH: 10 = input field ID 1, task status bit D0 * BBH: 11 = input field ID 1, task status bit D1. Depending on the input signal (interlaced or non-interlaced) and the task processing 50 Hz or field reduced processing with one or two tasks (see examples in Section 8.4.1.3), other combinations may also be possible, but the basic equations are the same. Table 13 Examples for vertical phase offset usage: global equations INPUT FIELD UNDER PROCESSING Upper input lines Upper input lines Lower input lines Lower input lines OUTPUT FIELD USED ABBREVIATION INTERPRETATION upper output lines lower output lines upper output lines lower output lines UP-UP UP-LO LO-UP LO-LO EQUATION FOR PHASE OFFSET CALCULATION (DECIMAL VALUES) PHO + 16 YSCY[15:0] PHO + ------------------------------ + 16 64 PHO YSCY[15:0] PHO + -----------------------------64 2004 Jul 22 59 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 14 Vertical phase offset usage; assignment of the phase offsets DETECTED INPUT FIELD ID 0 = upper lines TASK STATUS BIT 0 VERTICAL PHASE OFFSET YPY0[7:0] and YPC0[7:0] CASE SAF7118 EQUATION TO BE USED case 1(1) UP-UP (PHO) case 2(2) UP-UP case 3(3) UP-LO case 1 case 2 case 3 case 1 UP-UP (PHO) UP-LO UP-UP YSCY[15:0] LO-LO PHO + ------------------------------ - 16 64 LO-UP LO-LO YSCY[15:0] LO-LO PHO + ------------------------------ - 16 64 LO-LO LO-UP 0 = upper lines 1 YPY1[7:0] and YPC1[7:0] 1 = lower lines 0 YPY2[7:0] and YPC2[7:0] case 2 case 3 1 = lower lines 1 YPY3[7:0] and YPC3[7:0] case 1 case 2 case 3 Notes 1. Case 1: OFIDC[90H[6]] = 0; scaler input field ID as output ID; back-end interprets output field ID at logic 0 as upper output lines. 2. Case 2: OFIDC[90H[6]] = 1; task status bit as output ID; back-end interprets output field ID at logic 0 as upper output lines. 3. Case 3: OFIDC[90H[6]] = 1; task status bit as output ID; back-end interprets output field ID at logic 1 as upper output lines. 8.5 VBI data decoder and capture (subaddresses 40H to 7FH) The definition for line 24 is valid for the rest of the corresponding field, normally no text data (video data) should be selected there (LCR24_[7:0] = FFH) to stop the activity of the VBI data slicer during active video. To adjust the slicers processing to the input signal source, there are offsets in the horizontal and vertical direction available: parameters HOFF[10:0] 5BH[2:0] 59H[7:0], VOFF[8:0] 5BH[4] 5AH[7:0] and FOFF[5BH[7]]. Contrary to the scalers counting, the slicers offsets define the position of the H and V trigger events related to the processed video field. The trigger events are the falling edge of HREF and the falling edge of V123 from the decoder processing part. The relationship of these programming values to the input signal and the recommended values are given in Tables 5 to 8. The SAF7118 contains a versatile VBI data decoder. The implementation and programming model is in accordance with the VBI data slicer built into the multimedia video data acquisition circuit SAA5284. The circuitry recovers the actual clock phase during the clock run-in period, slices the data bits with the selected data rate, and groups them into bytes. The result is buffered into a dedicated VBI data FIFO with a capacity of 2 x 56 bytes (2 x 14 Dwords). The clock frequency, signal source, field frequency and accepted error count must be defined in subaddress 40H. The supported VBI data standards are shown in Table 15. For lines 2 to 24 of a field, per VBI line, 1 of 16 standards can be selected (LCR24_[7:0] to LCR2_[7:0] in 57H[7:0] to 41H[7:0]: 23 x 2 x 4 bit programming bits). 2004 Jul 22 60 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 15 Data types supported by the data slicer block DT[3:0] 62H[3:0] 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 US NABTS MOJI (Japanese) no sliced data transmitted (video data selected) 5.7272 5.7272 5 STANDARD TYPE teletext EuroWST, CCST European closed caption VPS wide screen signalling bits US teletext (WST) US closed caption (line 21) (video data selected) (raw data selected) teletext VITC/EBU time codes (Europe) VITC/SMPTE time codes (USA) DATA RATE (Mbit/s) 6.9375 0.500 5 5 5.7272 0.503 5 5 6.9375 1.8125 1.7898 FRAMING CODE 27H 001 9951H 1E3C1FH 27H 001 none none programmable programmable programmable reserved programmable programmable none NABTS open disable SAF7118 FC WINDOW WST625 CC625 VPS WSS WST525 CC525 disable disable general text VITC625 VITC525 HAM CHECK always always optional optional programmable (A7H) Japtext Japanese format switch (L20/22) 5 8.6 Image port output formatter (subaddresses 84H to 87H) The output interface consists of a FIFO for video and for sliced text data, an arbitration circuit, which controls the mixed transfer of video and sliced text data over the I port and a decoding and multiplexing unit, which generates the 8 or 16-bit wide output data stream and the accompanied reference and supporting information. The clock for the output interface can be derived from an internal clock, decoder, expansion port, or an externally provided clock which is appropriate for e.g. VGA and frame buffer. The clock can be up to 33 MHz. The scaler provides the following video related timing reference events (signals), which are available on pins as defined by subaddresses 84H and 85H: * Output field ID * Start and end of vertical active video range * Start and end of active video line * Data qualifier or gated clock * Actually activated programming page (if CONLH is used) * Threshold controlled FIFO filling flags (empty, full, filled) * Sliced data marker. 2004 Jul 22 61 The discontinuous data stream at the scaler output is accompanied by a data valid flag (or data qualifier), or is transported via a gated clock. Clock cycles with invalid data on the I port data bus (including the HPD pins in 16-bit output mode) are marked with code 00H. The output interface also arbitrates the transfer between scaled video data and sliced text data over the I port output. The bits VITX1 and VITX0 (subaddress 86H) are used to control the arbitration. As a further operation the serialization of the internal 32-bit Dwords to 8-bit or optional 16-bit output, as well as the insertion of the extended ITU 656 codes (SAV/EAV for video data, ANC or SAV/EAV codes for sliced text data) are done here. For handshake with the VGA controller, or other memory or bus interface circuitry, programmable FIFO flags are provided; see Section 8.6.2. Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.6.1 SCALER OUTPUT FORMATTER (SUBADDRESSES 93H AND C3H) SAF7118 The output formatter organizes the packing into the output FIFO. The following formats are available: Y-CB-CR 4 : 2 : 2, Y-CB-CR 4 : 1 : 1, Y-CB-CR 4 : 2 : 0, Y-CB-CR 4 : 1 : 0 and Y only (e.g. for raw samples). The formatting is controlled by FSI[2:0] 93H[2:0], FOI[1:0] 93H[4:3] and FYSK[93H[5]]. The data formats are defined on Dwords, or multiples, and are similar to the video formats as recommended for PCI multimedia applications (compares to SAA7146A), but planar formats are not supported. Table 16 Byte stream for different output formats OUTPUT FORMAT Y-CB-CR 4 : 2 : 2 Y-CB-CR 4 : 1 : 1 Y only CB0 CB0 Y0 Y0 Y0 Y1 CR0 CR0 Y2 FSI[2:0] defines the horizontal packing of the data, FOI[1:0] defines how many Y only lines are expected, before a Y/C line will be formatted. If FYSK is set to logic 0 preceding Y only lines will be skipped, and the output will always start with a Y/C line. Additionally the output formatter limits the amplitude range of the video data (controlled by ILLV[85H[5]]); see Table 18. BYTE SEQUENCE FOR 8-BIT OUTPUT MODES Y1 Y1 Y3 CB2 CB4 Y4 Y2 Y2 Y5 CR2 CR4 Y6 Y3 Y3 Y7 CB4 Y4 Y8 Y4 Y5 Y9 CR4 Y6 Y10 Y5 Y7 Y11 CB6 CB 8 Y12 Y6 Y8 Y13 Table 17 Explanation to Table 16 NAME CBn Yn CRn EXPLANATION CB (B - Y) colour difference component, pixel number n = 0, 2, 4 to 718 Y (luminance) component, pixel number n = 0, 1, 2, 3 to 719 CR (R - Y) colour difference component, pixel number n = 0, 2, 4 to 718 Table 18 Limiting range on I port LIMIT STEP ILLV[85H[5]] 0 1 8.6.2 VALID RANGE DECIMAL VALUE 1 to 254 8 to 247 VIDEO FIFO (SUBADDRESS 86H) HEXADECIMAL VALUE 01 to FE 08 to F7 These are: * The FIFO Almost Empty (FAE) flag * The FIFO Combined Flag (FCF) or FIFO filled, which is set at almost full level and reset, with hysteresis, only after the level crosses below the almost empty mark * The FIFO Almost Full (FAF) flag * The FIFO Overflow (FOVL) flag. The trigger levels for FAE and FAF are programmable by FFL[1:0] 86H[3:2] (16, 24, 28, full) and FEL[1:0] 86H[1:0] (16, 8, 4, empty). The state of this flag can be seen on the pins IGP0 or IGP1. The pin mapping is defined by subaddresses 84H and 85H; see Section 9.6. 62 SUPPRESSED CODES (HEXADECIMAL VALUE) LOWER RANGE 00 00 to 07 UPPER RANGE FF F8 to FF The video FIFO at the scaler output contains 32 Dwords. That corresponds to 64 pixels in 16-bit Y-CB-CR 4 : 2 : 2 format. But as the entire scaler can act as a pipeline buffer, the actual available buffer capacity for the image port is much higher, and can exceed beyond a video line. The image port, and the video FIFO, can operate with the video source clock (synchronous mode) or with an externally provided clock (asynchronous and burst mode), as appropriate for the VGA controller or attached frame buffer. The video FIFO provides 4 internal flags, reporting to what extent the FIFO is actually filled. 2004 Jul 22 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.6.3 TEXT FIFO SAF7118 The data of the internal VBI data slicer is collected in the text FIFO before the transmission over the I port is requested (normally before the video window starts). It is partitioned into two FIFO sections. A complete line is filled into the FIFO before a data transfer is requested. So normally, one line of text data is ready for transfer, while the next text line is collected. Thus sliced text data is delivered as a block of qualified data, without any qualification gaps in the byte stream of the I port. The decoded VBI data is collected in the dedicated VBI data FIFO. After the capture of a line has been completed, the FIFO can be streamed through the image port, preceded by a header, giving line number and standard. The VBI data period can be signalled via the sliced data flag on pin IGP0 or IGP1. The decoded VBI data is lead by the ITU ancillary data header (DID[5:0] 5DH[5:0] at value <3EH) or by SAV/EAV codes selectable by DID[5:0] at value 3EH or 3FH. Pin IGP0 or IGP1 is set if the first byte of the ANC header is valid on the I port bus. It is reset if an SAV occurs. So it may frame multiple lines of text data output, in the event that the video processing starts with a distance of several video lines to the region of text data. Valid sliced data from the text FIFO is available on the I port as long as the IGP0 or IGP1 flag is set and the data qualifier is active on pin IDQ. The decoded VBI data is presented in two different data formats, controlled by bit RECODE. * RECODE = 1: values 00H and FFH will be recoded to even parity values 03H and FCH * RECODE = 0: values 00H and FFH may occur in the data stream as detected. 8.6.4 VIDEO AND TEXT ARBITRATION (SUBADDRESS 86H) If the video data is transferred without any interrupt and the video FIFO does not need to buffer any output pixel, the text data is inserted after the end of a scaled video line, normally during the blanking interval of the video. 8.6.5 DATA STREAM CODING AND REFERENCE SIGNAL GENERATION (SUBADDRESSES 84H, 85H AND 93H) As H and V reference signals are logic 1, active gate signals are generated, which frame the transfer of the valid output data. As an alternative to the gates, H and V trigger pulses are generated on the rising edges of the gates. Due to the dynamic FIFO behaviour of the complete scaler path, the output signal timing has no fixed timing relationship to the real-time input video stream. So fixed propagation delays, in terms of clock cycles, related to the analog input cannot be defined. The data stream is accompanied by a data qualifier. Additionally invalid data cycles are marked with code 00H. If ITU 656 like codes are not required, they can be suppressed in the output stream. As a further option, it is possible to provide the scaler with an external gating signal on pin ITRDY. Thereby making it possible to hold the data output for a certain time and to get valid output data in bursts of a guaranteed length. The sketched reference signals and events can be mapped to the I port output pins IDQ, IGPH, IGPV, IGP0 and IGP1. For flexible use the polarities of all the outputs can be modified. The default polarity for the qualifier and reference signals is logic 1 (active). Table 19 shows the relevant and supported SAV and EAV coding. Sliced text data and scaled video data are transferred over the same bus, the I port. The mixed transfer is controlled by an arbitration circuit. 2004 Jul 22 63 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... Table 19 SAV/EAV codes on I port 2004 Jul 22 2004 Jul 22 64 64 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input SAV/EAV CODES ON I PORT(1) (HEX) EVENT DESCRIPTION MSB(2) OF SAV/EAV BYTE = 0 FIELD ID = 0 Next pixel is FIRST pixel of any active line Previous pixel was LAST pixel of any active line, but not the last Next pixel is FIRST pixel of any V-blanking line Previous pixel was LAST pixel of the last active line or of any V-blanking line No valid data, don't capture and don't increment pointer Notes 1. The leading byte sequence is: FFH-00H-00H. 2. The MSB of the SAV/EAV code byte is controlled by: a) Scaler output data: task A MSB = CONLH[90H[7]]; task B MSB = CONLH[C0H[7]]. b) VBI data slicer output data: DID[5:0] 5DH[5:0] = 3EH MSB = 1; DID[5:0] 5DH[5:0] = 3FH MSB = 0. 0E 13 25 38 FIELD ID = 1 49 54 62 7F 00 MSB(2) OF SAV/EAV BYTE = 1 FIELD ID = 0 80 9D AB B6 FIELD ID = 1 C7 DA EC F1 HREF = active; VREF = active HREF = inactive; VREF = active HREF = active; VREF = inactive HREF = inactive; VREF = inactive IDQ pin inactive COMMENT invalid data or end of raw VBI line timing reference code FF 00 00 internal header IDI1 sliced data IDI2 D1_3 D1_4 D2_1 and filling data timing reference code BC FF 00 00 EAV invalid data 00 00 ... ... FF 00 00 00 00 EAV SAV SDID DC ... DDC_3 DDC_4 CS ... MHB549 D1_1 D1_2 ANC header 00 FF FF internal header DID SDID DC IDI1 sliced data IDI2 D1_3 D1_4 ... DDC_3 DDC_4 CS BC ANC data output is only filled up to the Dword boundary 00 00 ... ANC header active for DID (subaddress 5DH) <3EH Product specification Fig.37 Sliced data formats on the I port in 8-bit mode. SAF7118 SAF7118 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 20 Explanation to Fig.37 NAME SAV SDID DC start of active data; see Table 21 EXPLANATION SAF7118 sliced data identification: NEP(1), EP(2), SDID5 to SDID0, freely programmable via I2C-bus subaddress 5EH, D5 to D0, e. g. to be used as source identifier Dword count: NEP(1), EP(2), DC5 to DC0. DC describes the number of succeeding 32-bit words: * For SAV/EAV mode DC is fixed to 11 Dwords (byte value 4BH) * For ANC mode it is: DC = 14(C + n), where C = 2 (the two data identification bytes IDI1 and IDI2) and n = number of decoded bytes according to the chosen text standard. It should be noted that the number of valid bytes inside the stream can be seen in the BC byte. IDI1 IDI2 Dn_m DDC_4 CS BC EAV Notes internal data identification 1: OP(3), FID (field 1 = 0, field 2 = 1), LineNumber8 to LineNumber3 = Dword 1 byte 1; see Table 21 internal data identification 2: OP(3), LineNumber2 to LineNumber0, DataType3 to DataType0 = Dword 1 byte 2; see Table 21 Dword number n, byte number m last Dword byte 4, note: for SAV/EAV framing DC is fixed to 0BH, missing data bytes are filled up; the fill value is A0H the check sum byte, the check sum is accumulated from the SAV (respectively DID) byte to the DDC_4 byte number of valid sliced bytes counted from the IDI1 byte end of active data; see Table 21 1. Inverted EP (bit D7); for EP see note 2. 2. Even parity (bit D6) of bits D5 to D0. 3. Odd parity (bit D7) of bits D6 to D0. 2004 Jul 22 65 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 21 Bytes stream of the data slicer NICK NAME DID, SAV, EAV COMMENT subaddress 5DH = 00H subaddress 5DH; D5 = 1 subaddress 5DH D5 = 3EH; note 5 subaddress 5DH D5 = 3FH; note 5 SDID DC(8) IDI1 IDI2 CS BC Notes 1. NEP = inverted EP (see note 2). 2. EP = Even Parity of bits D5 to D0. 3. FID = 0: field 1; FID = 1: field 2. check sum byte valid byte count programmable via subaddress 5EH D7 NEP(1) NEP(1) 1 0 NEP(1) NEP(1) OP(9) OP(9) CS6 OP(9) D6 EP(2) EP(2) FID(3) FID(3) EP(2) EP(2) FID(3) LN2(10) CS6 0 D5 0 0 V(6) V(6) D4 1 D3 0 D2 FID(3) SAF7118 D1 I1(4) D0 I0(4) D4[5DH] D3[5DH] D2[5DH] D1[5DH] D0[5DH] H(7) H(7) P3 P3 P2 P2 P1 P1 P0 P0 D5[5EH] D4[5EH] D3[5EH] D2[5EH] D1[5EH] D0[5EH] DC5 LN8(10) LN1(10) CS5 CNT5 DC4 LN7(10) LN0(10) CS4 CNT4 DC3 LN6(10) DT3(11) CS3 CNT3 DC2 LN5(10) DT2(11) CS2 CNT2 DC1 LN4(10) DT1(11) CS1 CNT1 DC0 LN3(10) DT0(11) CS0 CNT0 4. I1 = 0 and I0 = 0: before line 1; I1 = 0 and I0 = 1: lines 1 to 23; I1 = 1 and I0 = 0: after line 23; I1 = 1 and I0 = 1: line 24 to end of field. 5. Subaddress 5DH at 3EH and 3FH are used for ITU 656 like SAV/EAV header generation; recommended value. 6. V = 0: active video; V = 1: blanking. 7. H = 0: start of line; H = 1: end of line. 8. DC = Data Count in Dwords according to the data type. 9. OP = Odd Parity of bits D6 to D0. 10. LN = Line Number. 11. DT = Data Type according to table. 2004 Jul 22 66 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.7 Audio clock generation (subaddresses 30H to 3FH) See Table 22 for examples. SAF7118 The SAF7118 incorporates the generation of a field-locked audio clock as an auxiliary function for video capture. An audio sample clock, that is locked to the field frequency, ensures that there is always the same predefined number of audio samples associated with a field, or a set of fields. This ensures synchronous playback of audio and video after digital recording (e.g. capture to hard disk), MPEG or other compression, or non-linear editing. 8.7.1 MASTER AUDIO CLOCK Remark: For standard applications the synthesized audio clock AMCLK can be used directly as master clock and as input clock for port AMXCLK (short cut) to generate ASCLK and ALRCLK. For high-end applications it is recommended to use an external analog PLL circuit to enhance the performance of the generated audio clock. The audio clock is synthesized from the same crystal frequency as the line-locked video clock is generated. The master audio clock is defined by the parameters: * Audio master Clocks Per Field, ACPF[17:0] 32H[1:0] 31H[7:0] 30H[7:0] according to the equation: audio frequency ACPF[17:0] = round ----------------------------------------- field frequency- * Audio master Clocks Nominal Increment, ACNI[21:0] 36H[5:0] 35H[7:0] 34H[7:0] according to the equation: audio frequency 23 ACNI[21:0] = round -------------------------------------------- x 2 crystal frequency Table 22 Programming examples for audio master clock generation XTALO (MHz) FIELD (Hz) ACPF DECIMAL HEX DECIMAL ACNI HEX AMCLK = 256 x 48 kHz (12.288 MHz) 32.11 24.576 50 59.94 50 59.94 245760 205005 - - 225792 188348 225792 188348 3C000 320CD - - 37200 2DFBC 37200 2DFBC 3210190 3210190 - - 2949362 2949362 3853517 3853 517 30FBCE 30FBCE - - 2D00F2 2D00F2 3ACCCD 3ACCCD AMCLK = 256 x 44.1 kHz (11.2896 MHz) 32.11 24.576 50 59.94 50 59.94 AMCLK = 256 x 32 kHz (8.192 MHz) 32.11 24.576 50 59.94 50 59.94 163840 136670 163840 136670 67 28000 215DE 28000 215DE 2140127 2140127 2796203 2796203 20A7DF 20A7DF 2AAAAB 2AAAAB 2004 Jul 22 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 8.7.2 SIGNALS ASCLK AND ALRCLK SAF7118 Two binary divided signals ASCLK and ALRCLK are provided for slower serial digital audio signal transmission and for channel-select. The frequencies of these signals are defined by the following parameters: * SDIV[5:0] 38H[5:0] according to the equation: f AMXCLK f AMXCLK f ASCLK = ------------------------------------- SDIV[5:0] = ------------------- - 1 ( SDIV + 1 ) x 2 2f ASCLK f ASCLK f ASCLK * LRDIV[5:0] 39H[5:0] according to the equation: f ALRCLK = -------------------------- LRDIV[5:0] = ---------------------LRDIV x 2 2f ALRCLK See Table 23 for examples. Table 23 Programming examples for ASCLK/ALRCLK clock generation AMXCLK (MHz) 12.288 11.2896 8.192 8.7.3 ASCLK (kHz) 1536 768 1411.2 2822.4 1024 2048 SDIV DECIMAL 3 7 3 1 3 1 HEX 03 07 03 01 03 01 ALRCLK (kHz) 48 44.1 32 LRDIV DECIMAL 16 8 16 32 16 32 HEX 10 08 10 10 10 10 OTHER CONTROL SIGNALS Further control signals are available to define reference clock edges and vertical references; see Table 24. Table 24 Control signals for reference clock edges and vertical references SIGNAL APLL[3AH[3]] Audio PLL mode 0 = PLL closed 1 = PLL open AMVR[3AH[2]] Audio Master clock Vertical Reference 0 = internal V 1 = external V LRPH[3AH[1]] ALRCLK phase 0 = invert ASCLK, ALRCLK edges triggered by falling edge of ASCLK 1 = don't invert ASCLK, ALRCLK edges triggered by rising edge of ASCLK SCPH[3AH[0]] ASCLK phase 0 = invert AMXCLK, ASCLK edges triggered by falling edge of AMXCLK 1 = don't invert AMXCLK, ASCLK edges triggered by rising edge of AMXCLK DESCRIPTION 2004 Jul 22 68 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 9 INPUT/OUTPUT INTERFACES AND PORTS SAF7118 The SAF7118 has 5 different I/O interfaces: * Analog video input interface, for analog CVBS and/or Y and C input signals and/or component video signals * Audio clock port * Digital real-time signal port (RT port) * Digital video expansion port (X port), for unscaled digital video input and output * Digital image port (I port) for scaled video data output and programming * Digital host port (H port) for extension of the image port or expansion port from 8 to 16-bit. 9.1 Analog terminals Component signals with e.g. sync-on-Y or sync-on-green are also supported; they are fed to two ADC channels, one for the video contents, the other for sync conversion. Additionally, there are four differential reference inputs, which must be connected to ground via a capacitor equivalent to the decoupling capacitors at the 16 inputs. There are no peripheral components required other than these decoupling capacitors and 18 /56 termination resistors, one set per connected input signal; see application example in Fig.47. Four anti-alias filters are integrated. Clamp and gain control for the four ADCs are also integrated. An analog video output (pin AOUT) is provided for testing purposes. The SAF7118 has 16 analog inputs AI41 to AI44, AI31 to AI34, AI21 to AI24 and AI11 to AI14 for composite video CVBS or S-video Y/C signal pairs or component video input signals RGB plus separate sync (or Y-PB-PR plus separate sync). Table 25 Analog pin description SYMBOL AI11 to AI14 AI21 to AI24 AI31 to AI34 AI41 to AI44 AOUT PIN(1) J2, K1, K2 and L3 (27, 29, 31 and 34) G4, G3, H2 and J3 (19, 21, 23 and 26) E3, F2, F3 and G1 (11, 13, 15 and 18) B1, D2, D1 and E1 (2, 5, 7 and 10) M1 (36) O I analog video output, for test purposes analog reference pins for differential ADC operation; connect to ground via 47 nF AOSL2 to AOSL0 - I/O I DESCRIPTION analog video signal inputs, e.g. 16 CVBS signals or eight Y/C pairs, or four RGB plus separate sync (or Y-PB-PR plus separate sync) signal groups can be connected simultaneously to this device; many combinations are possible; see Figs 51 to 91 BIT MODE5 to MODE0 AI1D, AI2D, K3, H1, F1 and D3 AI3D and AI4D (30, 22, 14 and 6) Note 1. Pin numbers for QFP160 in parenthesis. 2004 Jul 22 69 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 9.2 Audio clock signals SAF7118 The SAF7118 also synchronizes the audio clock and sampling rate to the video frame rate, via a very slow PLL. This ensures that the multimedia capture and compression processes always gather the same predefined number of samples per video frame. Table 26 Audio clock pin description SYMBOL PIN(1) I/O AMCLK AMXCLK P11 (72) M12 (76) N11 (74) P12 (75) O I DESCRIPTION audio master clock output An audio master clock AMCLK and two divided clocks ASCLK and ALRCLK are generated: * ASCLK: can be used as audio serial clock * ALRCLK: audio left/right channel clock. The ratios are programmable; see Section 8.7. BIT ACPF[17:0] 32H[1:0] 31H[7:0] 30H[7:0] and ACNI[21:0] 36H[5:0] 35H[7:0] 34H[7:0] - external audio master clock input for the clock division circuit, can be directly connected to output AMCLK for standard applications serial audio clock output, can be synchronized to rising or falling edge of AMXCLK ASCLK ALRCLK Note O O SDIV[5:0] 38H[5:0] and SCPH[3AH[0]] audio channel (left/right) clock output, can be LRDIV[5:0] 39H[5:0] and LRPH[3AH[1]] synchronized to rising or falling edge of ASCLK 1. Pin numbers for QFP160 in parenthesis. 9.3 Clock and real-time synchronization signals The Line-Locked Clock (LLC) is the double pixel clock of nominal 27 MHz. It is locked to the selected video input, generating baseband video pixels according to "ITU recommendation 601". In order to support interfacing circuits, a direct pixel clock (LLC2) is also provided. The pins for line and field timing reference signals are RTCO, RTS1 and RTS0. Various real-time status information can be selected for the RTS pins. The signals are always available (output) and reflect the synchronization operation of the decoder part in the SAF7118. The function of the RTS1 and RTS0 pins can be defined by bits RTSE1[3:0] 12H[7:4] and RTSE0[3:0] 12H[3:0]. For the generation of the line-locked video (pixel) clock LLC, and of the frame-locked audio serial bit clock, a crystal accurate frequency reference is required. An oscillator is built-in for fundamental or third harmonic crystals. The supported crystal frequencies are 32.11 or 24.576 MHz (defined during reset by strapping pin ALRCLK). Alternatively pin XTALI can be driven from an external single-ended oscillator. The crystal oscillation can be propagated as a clock to other ICs in the system via pin XTOUT. 2004 Jul 22 70 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 27 Clock and real-time synchronization signals SYMBOL PIN(1) I/O Crystal oscillator XTALI XTALO XTOUT B4 (155) A3 (156) A2 (158) I O O input for crystal oscillator or reference clock output of crystal oscillator reference (crystal) clock output drive (optional) - - DESCRIPTION SAF7118 BIT XTOUTE[14H[3]] Real-time signals (RT port) LLC LLC2 RTCO P4 (46) N5 (48) L10 (71) M10 (69) N10 (70) O O O line-locked clock, nominal 27 MHz, double pixel clock locked to the selected video input signal line-locked pixel clock, nominal 13.5 MHz - - real-time control output, transfers real-time status information - supporting RTC level 3.1 (see document "RTC Functional Description", available on request) real-time status information line 0, can be programmed to carry various RTSE0[3:0] 12H[3:0] real-time information; see Table 57 real-time status information line 1, can be programmed to carry various RTSE1[3:0] 12H[7:4] real-time information; see Table 58 RTS0 RTS1 Note O O 1. Pin numbers for QFP160 in parenthesis. 9.4 9.4.1 Interrupt handling INTERRUPT FLAGS DCSTD[1:0]: detected colour standard has changed or colour lost. COPRO, COLSTR and TYPE3: various levels of copy protection have changed. 9.4.1.3 VBI data slicer The pin INT_A is an open-drain output (active LOW). All flags can be independently enabled. For the default setting all flags are disabled after reset. For the description of interrupt mask registers; see Section 15.4. 9.4.1.1 Power state VPSV: VPS identification found or lost. PPV: PALplus identification found or lost. CCV: Closed caption identification found or lost. 9.4.1.4 Scaler PRDON: a power fail has been detected during normal operation, the device needs re-programming. 9.4.1.2 Video decoder INTL: interlaced/non-interlaced source detected. HLCK: horizontal PLL state changed (locked unlocked). HLVLN: vertical lock state changed (locked unlocked). FIDT: detected field frequency has changed (50 Hz 60 Hz). RDCAP: ready for capture (true false). ERROF: scaler output formatting error detected. 9.4.2 STATUS READING CONDITIONS The status information read after an interrupt will always be the LATEST state, that means the status will not be `frozen' when an interrupt is being generated. Therefore, if there is a long time between interrupt generation and status reading, the original trigger condition might have been overridden by the present state. 2004 Jul 22 71 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 9.4.3 ERASING CONDITIONS SAF7118 The expansion port consists of two groups of signals/pins: * 8-bit data, I/O, regularly components video Y-CB-CR 4 : 2 : 2, i.e. CB-Y-CR-Y, byte serial, exceptionally raw video samples (e.g. ADC test). In input mode the data bus can be extended to 16-bit by pins HPD7 to HPD0. * Clock, synchronization and auxiliary signals, accompanying the data stream, I/O. As output, these are direct copies of the decoder signals. The data transfers through the expansion port represent a single D1 port, with half duplex mode. The SAV and EAV codes may be inserted optionally for data input (controlled by bit XCODE[92H[3]]). The input/output direction is switched for complete fields only. The status flags are grouped into four 8-bit registers. The interrupt flag will only be cleared on a read access to the status register in which the signal is located which caused the interrupt. This implies that it is sufficient to clear the interrupt by reading only those registers which have been enabled by their corresponding masks. Priority: If a new trigger condition occurs at the SAME time (clock) on which a status is being read, the flag will NOT be cleared. 9.5 Video expansion port (X port) The expansion port is intended for transporting video streams image data from other digital video circuits such as MPEG encoder/decoder and video phone codec, to the image port (I port). Table 28 Signals dedicated to the expansion port SYMBOL XPD7 to XPD0 PIN(1) I/O DESCRIPTION BIT OFTS[2:0] 13H[2:0], 91H[7:0] and C1H[7:0] XCKS[92H[0]] C11, A11, B10, A10, I/O X port data: in output mode controlled by decoder section, B9, A9, B8 and A8 data format see Table 29; in input mode Y-CB-CR 4 : 2 : 2 (127, 128, 130, 131, serial input data or luminance part of a 16-bit 134, 135, 138 and 139) Y-CB-CR 4 : 2 : 2 input A7 (143) I/O clock at expansion port: if output, then copy of LLC; as input normally a double pixel clock of up to 32 MHz or a gated clock (clock gated with a qualifier) I/O data valid flag of the expansion port input (qualifier): if output, then decoder (HREF and VGATE) gate (see Fig.30) O data request flag = ready to receive, to work with optional buffer in external device, to prevent internal buffer overflow; second function: input related task flag A/B XCLK XDQ B7 (144) - XRDY A6 (146) XRQT[83H[2]] XRH C7 (141) I/O horizontal reference signal for the X port: as output: HREF or HS from the decoder (see Fig.30); as input: a reference edge for horizontal input timing and a polarity for input field ID detection can be defined I/O vertical reference signal for the X port: as output: V123 or field ID from the decoder, see Figs 28 and 29; as input: a reference edge for vertical input timing and for input field ID detection can be defined I port control: switches X port input 3-state XRHS[13H[6]], XFDH[92H[6]] and XDH[92H[2]] XRVS[1:0] 13H[5:4], XFDV[92H[7]] and XDV[1:0] 92H[5:4] XPE[1:0] 83H[1:0] XRV D8 (140) XTRI Note B11 (126) 1. Pin numbers for QFP160 in parenthesis. 2004 Jul 22 72 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 9.5.1 X PORT CONFIGURED AS OUTPUT SAF7118 If data output is enabled at the expansion port, then the data stream from the decoder is presented. The data format of the 8-bit data bus is dependent on the chosen data type, selectable by the line control registers LCR2 to LCR24; see Table 4. In contrast to the image port, the sliced data format is not available on the expansion port. Instead, raw CVBS samples are always transferred if any sliced data type is selected. Some details of data types on the expansion port are as follows: * Active video (data type 15): contains component Y-CB-CR 4 : 2 : 2 signal, 720 active pixels per line. The amplitude and offsets are programmable via DBRI7 to DBRI0, DCON7 to DCON0, DSAT7 to DSAT0, OFFU1, OFFU0, OFFV1 and OFFV0. The nominal levels are illustrated in Fig.19. * Test line (data type 6): is similar to the active video format, with some constraints within the data processing: - adaptive chrominance comb filter, vertical filter (chrominance comb filter for NTSC standards, PAL phase error correction) within the chrominance processing are disabled - adaptive luminance comb filter, peaking and chrominance trap are bypassed within the luminance processing. This data type is defined for future enhancements. It could be activated for lines containing standard test signals within the vertical blanking period. Currently the most sources do not contain test lines. The nominal levels are illustrated in Fig.19. * Raw samples (data types 0 to 5 and 7 to 14): CB-CR samples are similar to data type 6, but CVBS samples are transferred instead of processed luminance samples within the Y time slots. Table 29 Data format on the expansion port BLANKING PERIOD ... 80 TIMING REFERENCE CODE (HEX)(1) The amplitude and offset of the CVBS signal is programmable via RAWG7 to RAWG0 and RAWO7 to RAWO0; see Chapter 15, Tables 64 and 65. The nominal levels are illustrated in Fig.20. The relationship of LCR programming to line numbers is described in Section 8.3, Tables 5 to 8. The data type selections by LCR are overruled by setting OFTS2 = 1 (subaddress 13H bit D2). This setting is mainly intended for device production test. The VPO-bus carries the upper or lower 8 bits of the two ADCs depending on the OFTS[1:0] 13H[1:0] settings; see Table 59. The input configuration is done via MODE[5:0] 02H[5:0] settings; see Table 41. If a Y/C mode is selected, the expansion port carries the multiplexed output signals of both ADCs, and in CVBS mode the output of only one ADC. No timing reference codes are generated in this mode. Remark: The LSBs (bit D0) of the ADCs are also available on pin RTS0; see Table 57. The SAV/EAV timing reference codes define the start and end of valid data regions. The ITU-blanking code sequence `- 80 - 10 - 80 - 10 -...' is transmitted during the horizontal blanking period between EAV and SAV. The position of the F-bit is constant in accordance with ITU 656; see Tables 31 and 32. The V-bit can be generated in two different ways (see Tables 31 and 32) controlled via OFTS1 and OFTS0; see Table 59. The F and V bits change synchronously with the EAV code. 720 PIXELS Y-CB-CR 4 : 2 : 2 DATA(2) TIMING REFERENCE CODE (HEX)(1) BLANKING PERIOD 10 ... 10 FF 00 00 SAV CB0 Y0 CR0 Y1 CB2 Y2 ... CR718 Y719 FF 00 00 EAV 80 Notes 1. The generation of the timing reference codes can be suppressed by setting OFTS[2:0] to 010; see Table 59. In this event the code sequence is replaced by the standard `- 80 - 10 -' blanking values. 2. If raw samples or sliced data are selected by the line control registers (LCR2 to LCR24), the Y samples are replaced by CVBS samples. 2004 Jul 22 73 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 30 SAV/EAV format on expansion port XPD7 to XPD0 BIT D7 1 field bit 1st field: F = 0 2nd field: F = 1 BIT D6 (F) BIT D5 (V) vertical blanking bit VBI: V = 1 active video: V = 0 format BIT D4 (H) SAF7118 BIT D3 BIT D2 BIT D1 BIT D0 (P3) (P2) (P1) (P0) reserved; evaluation not H = 0 in SAV format recommended (protection bits according to ITU 656) H = 1 in EAV format for vertical timing see Tables 31 and 32 Table 31 525 lines/60 Hz vertical timing V LINE NUMBER 1 to 3 4 to 19 20 21 22 to 261 262 263 264 and 265 266 to 282 283 284 285 to 524 525 F (ITU 656) OFTS[2:0] = 000 (ITU 656) 1 0 0 0 0 0 0 0 1 1 1 1 1 1 1 0 0 0 0 0 1 1 0 0 0 0 OFTS[2:0] = 001 according to selected VGATE position type via VSTA and VSTO (subaddresses 15H to 17H); see Tables 61 to 63 Table 32 625 lines/50 Hz vertical timing V LINE NUMBER 1 to 22 23 24 to 309 310 311 and 312 313 to 335 336 337 to 622 623 624 and 625 F (ITU 656) OFTS[2:0] = 000 (ITU 656) 0 0 0 0 0 1 1 1 1 1 1 0 0 0 1 1 0 0 0 1 OFTS[1:0] = 10 according to selected VGATE position type via VSTA and VSTO (subaddresses 15H to 17H); see Tables 61 to 63 2004 Jul 22 74 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 9.5.2 X PORT CONFIGURED AS INPUT SAF7118 If the data input mode is selected at the expansion port, then the scaler can select its input data stream from the on-chip video decoder, or from the expansion port (controlled by bit SCSRC[1:0] 91H[5:4]). Byte serial Y-CB-CR 4 : 2 : 2, or subsets for other sampling schemes, or raw samples from an external ADC may be input (see also bits FSC[2:0] 91H[2:0]). The input stream must be accompanied by an external clock (XCLK), qualifier XDQ and reference signals XRH and XRV. Instead of the reference signal, embedded SAV and EAV codes according to ITU 656 are also accepted. The protection bits are not evaluated. XRH and XRV carry the horizontal and vertical synchronization signals for the digital video stream through the expansion port. The field ID of the input video stream is carried in the phase (edge) of XRV and state of XRH, or directly as FS (frame sync, odd/even signal) on the XRV pin (controlled by XFDV[92H[7]], XFDH[92H[6]] and XDV[1:0] 92H[5:4]). The trigger events on XRH (rising/falling edge) and XRV (rising/falling/both edges) for the scalers acquisition window are defined by XDV[1:0] 92H[5:4] and XDH[92H[2]]. The signal polarity of the qualifier can also be defined (bit XDQ[92H[1]]). Alternatively to a qualifier, the input clock can be applied to a gated clock (clock gated with a data qualifier, controlled by bit XCKS[92H[0]]). In this event, all input data will be qualified. As the VBI data slicer may have different requirements for its input reference signals from X port XRV, XRH, XDQ, XCLK and XPD7 to XPD0, a second set of parameters is available for defining the meaning of the X port input signals and polarities for the VBI data slicer input path. These bits are defined in subaddresses 81H and 82H. 9.6 Image port (I port) The data formats at the image port are defined in Dwords of 32 bits (4 bytes), such as the related FIFO structures. However the physical data stream at the image port is only 16-bit or 8-bit wide; in 16-bit mode data pins HPD7 to HPD0 are used for chrominance data. The four bytes of the Dwords are serialized in words or bytes. Available formats are as follows: * Y-CB-CR 4 : 2 : 2 * Y-CB-CR 4 : 1 : 1 * Raw samples * Decoded VBI data. For handshake with the receiving VGA controller, or other memory or bus interface circuitry, F, H and V reference signals and programmable FIFO flags are provided. The information is provided on pins IGP0, IGP1, IGPH and IGPV. The functionality on these pins is controlled via subaddresses 84H and 85H. VBI data is collected over an entire line in its own FIFO, and transferred as an uninterrupted block of bytes. Decoded VBI data can be signed by the VBI flag on pin IGP0 or IGP1. As scaled video data and decoded VBI data may come from different and asynchronous sources, an arbitration scheme is needed. Normally the VBI data slicer has priority. The image port consists of the pins and/or signals, as listed in Table 33. For pin constrained applications, or interfaces, the relevant timing and data reference signals can also get encoded into the data stream. Therefore the corresponding pins do not need to be connected. The minimum image port configuration requires 9 pins only, i.e. 8 pins for data including codes, and 1 pin for clock or gated clock. The inserted codes are defined in close relationship to the ITU-R BT.656 (D1) recommendation, where possible. The image port transfers data from the scaler as well as from the VBI data slicer, if selected (maximum 33 MHz). The reference clock is available at the ICLK pin, as an output, or as an input (maximum 33 MHz). As output, ICLK is derived from the line-locked decoder or expansion port input clock. The data stream from the scaler output is normally discontinuous. Therefore valid data during a clock cycle is accompanied by a data qualifying (data valid) flag on pin IDQ. For pin constrained applications the IDQ pin can be programmed to function as a gated clock output (bit ICKS2[80H[2]]). 2004 Jul 22 75 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input The following deviations from "ITU 656 recommendation" are implemented at the SAF7118 image port interface: * SAV and EAV codes are only present in those lines, where data is to be transferred, i.e. active video lines, or VBI raw samples, no codes for empty lines * There may be more or less than 720 pixels between SAV and EAV * Data content and the number of clock cycles during horizontal and vertical blanking is undefined, and may not be constant * Data stream may be interleaved with not-valid data codes, 00H, but SAV and EAV 4-byte codes are not interleaved with not-valid data codes * There may be an irregular pattern of not-valid data, or IDQ, and as a result, CB-Y-CR-Y is not in a fixed phase to a regular clock divider * VBI raw sample streams are enveloped with SAV and EAV, like normal video Table 33 Signals dedicated to the image port SYMBOL IPD7 to IPD0 PIN(1) I/O DESCRIPTION BIT SAF7118 * Decoded VBI data is transported as Ancillary (ANC) data, two modes: - direct decoded VBI data bytes (8-bit) are directly placed in the ANC data field, 00H and FFH codes may appear in data block (violation to ITU-R BT.656) - recoded VBI data bytes (8-bit) directly placed in ANC data field, 00H and FFH codes will be recoded to even parity codes 03H and FCH to suppress invalid ITU-R BT.656 codes. There are no empty cycles in the ancillary code and its data field. The data codes 00H and FFH are suppressed (changed to 01H or FEH respectively) in the active video stream, as well as in the VBI raw sample stream (VBI pass-through). Optionally, the number range can be further limited. K11, J13, J14, I/O I port data H13, H14, H11, G12 and G14 (92 to 94, 97 to 100 and 102) M14 (84) I/O continuous reference clock at image port, can be input or output, as output decoder LLC or XCLK from X port O data valid flag at image port, qualifier, with programmable polarity; secondary function: gated clock ICODE[93H[7]], ISWP[1:0] 85H[7:6] and IPE[1:0] 87H[1:0] ICLK ICKS[1:0] 80H[1:0] and IPE[1:0] 87H[1:0] ICKS2[80H[2]], IDQP[85H[0]] and IPE[1:0] 87H[1:0] IDQ L13 (85) IGPH K12 (91) O horizontal reference output signal, copy of the IDH[1:0] 84H[1:0], IRHP[85H[1]] H gate signal of the scaler, with programmable and IPE[1:0] 87H[1:0] polarity; alternative function: HRESET pulse vertical reference output signal, copy of the IDV[1:0] 84H[3:2], IRVP[85H[2]] V gate signal of the scaler, with programmable and IPE[1:0] 87H[1:0] polarity; alternative function: VRESET pulse general purpose output signal for I port general purpose output signal for I port target ready input signals port control, switches I port into 3-state IDG12[86H[4]], IDG1[1:0] 84H[5:4], IG1P[85H[3]] and IPE[1:0] 87H[1:0] IDG02[86H[5]], IDG0[1:0] 84H[7:6], IG0P[85H[4]] and IPE[1:0] 87H[1:0] - IPE[1:0] 87H[1:0] IGPV K14 (90) O IGP1 IGP0 ITRDY ITRI Note K13 (89) L14 (87) N12 (77) L12 (86) O O I I 1. Pin numbers for QFP160 in parenthesis. 2004 Jul 22 76 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 9.7 Host port for 16-bit extension of video data I/O (H port) SAF7118 The H port pins HPD can be used for extension of the data I/O paths to 16-bit. The I port has functional priority. If I8_16[93H[6]] is set to logic 1 the output drivers of the H port are enabled depending on the I port enable control. For I8_16 = 0, the HPD output is disabled. Table 34 Signals dedicated to the host port SYMBOL HPD7 to HPD0 PIN(1) G13, F14, F13, E14, E12, E13, E11 and D14 (103, 105, 107 and 109 to 113) I/O I/O DESCRIPTION 16-bit extension for digital I/O (chrominance component) BIT IPE[1:0] 87H[1:0], ITRI[8FH[6]] and I8_16[93H[6]] Note 1. Pin numbers for QFP160 in parenthesis. 9.8 9.8.1 Basic input and output timing diagrams I port and X port I PORT OUTPUT TIMING 9.8.2 X PORT INPUT TIMING At the X port the input timing requirements are the same as those for the I port output. But different to those below: * It is not necessary to mark invalid cycles with a 00H code * No constraints on the input qualifier (can be a random pattern) * XCLK may be a gated clock (XCLK AND external XDQ). Remark: All timings illustrated in Figs 38 to 44 are given for an uninterrupted output stream (no handshake with the external hardware). The following diagrams illustrate the output timing via the I port. IGPH and IGPV are logic 1 active gate signals. If reference pulses are programmed, these pulses are generated on the rising edge of the logic 1 active gates. Valid data is accompanied by the output data qualifier on pin IDQ. In addition invalid cycles are marked with output code 00H. The IDQ output pin may be defined to be a gated clock output signal (ICLK AND internal IDQ). ICLK IDQ IPD [ 7:0 ] 00 FF 00 00 SAV 00 CB Y CR Y 00 CB Y CR Y 00 IGPH MHB550 Fig.38 Output timing I port for serial 8-bit data at start of a line (ICODE = 1). 2004 Jul 22 77 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 ICLK IDQ IPD [ 7:0 ] 00 CB Y CR Y 00 CB Y CR Y 00 IGPH MHB551 Fig.39 Output timing I port for serial 8-bit data at start of a line (ICODE = 0). ICLK IDQ IPD [ 7:0 ] 00 CB Y CR Y 00 CB Y CR Y 00 FF 00 00 EAV 00 IGPH MHB552 Fig.40 Output timing I port for serial 8-bit data at end of a line (ICODE = 1). 2004 Jul 22 78 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 ICLK IDQ IPD [ 7:0 ] 00 CB Y CR Y 00 CB Y CR Y 00 IGPH MHB553 Fig.41 Output timing I port for serial 8-bit data at end of a line (ICODE = 0). ICLK IDQ IPD [ 7:0 ] 00 FF 00 00 Y0 Y1 00 Y2 Y3 Yn - 1 Yn 00 FF 00 00 HPD [ 7:0 ] 00 00 SAV 00 CB CR 00 CB CR CB CR 00 00 EAV 00 IGPH MHB554 Fig.42 Output timing for 16-bit data output via I port and H port with codes (ICODE = 1), timing is like 8-bit output, but packages of 2 bytes per valid cycle. 2004 Jul 22 79 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, full pagewidth IDQ IGPH IGPV MHB555 Fig.43 H gate and V gate output timing. handbook, full pagewidth IDQ IGPH IGPV MHB555 Fig.44 Output timing for sliced VBI data in 8-bit serial output mode (dotted graphs for SAV/EAV mode). 2004 Jul 22 80 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 10 BOUNDARY SCAN TEST The SAF7118 has built-in logic and 5 dedicated pins to support boundary scan testing which allows board testing without special hardware (nails). The SAF7118 follows the "IEEE Std. 1149.1 - Standard Test Access Port and Boundary-Scan Architecture" set by the Joint Test Action Group (JTAG) chaired by Philips. The 5 special pins are Test Mode Select (TMS), Test Clock (TCK), Test Reset (TRST), Test Data Input (TDI) and Test Data Output (TDO). Table 35 BST instructions supported by the SAF7118 INSTRUCTION BYPASS EXTEST SAMPLE DESCRIPTION SAF7118 The Boundary Scan Test (BST) functions BYPASS, EXTEST, INTEST, SAMPLE, CLAMP and IDCODE are all supported; see Table 35. Details about the JTAG BST-TEST can be found in specification "IEEE Std. 1149.1". A file containing the detailed Boundary Scan Description Language (BSDL) description of the SAF7118 is available on request. This mandatory instruction provides a minimum length serial path (1 bit) between TDI and TDO when no test operation of the component is required. This mandatory instruction allows testing of off-chip circuitry and board level interconnections. This mandatory instruction can be used to take a sample of the inputs during normal operation of the component. It can also be used to preload data values into the latched outputs of the boundary scan register. This optional instruction is useful for testing when not all ICs have BST. This instruction addresses the bypass register while the boundary scan register is in external test mode. This optional instruction will provide information on the components manufacturer, part number and version number. This optional instruction allows testing of the internal logic (no customer support available). This private instruction allows testing by the manufacturer (no customer support available). When the IDCODE instruction is loaded into the BST instruction register, the identification register will be connected between pins TDI and TDO of the IC. The identification register will load a component specific code during the CAPTURE_DATA_REGISTER state of the TAP controller and this code can subsequently be shifted out. At board level this code can be used to verify component manufacturer, type and version number. The device identification register contains 32 bits, numbered 31 to 0, where bit D31 is the most significant bit (nearest to TDI) and bit D0 is the least significant bit (nearest to TDO); see Fig.45. CLAMP IDCODE INTEST USER1 10.1 Initialization of boundary scan circuit The Test Access Port (TAP) controller of an IC should be in the reset state (TEST_LOGIC_RESET) when the IC is in functional mode. This reset state also forces the instruction register into a functional instruction such as IDCODE or BYPASS. To solve the power-up reset, the standard specifies that the TAP controller will be forced asynchronously to the TEST_LOGIC_RESET state by setting the TRST pin LOW. 10.2 Device identification codes A device identification register is specified in "IEEE Std. 1149.1b-1994". It is a 32-bit register which contains fields for the specification of the IC manufacturer, the IC part number and the IC version number. Its biggest advantage is the possibility to check for the correct ICs mounted after production and determination of the version number of ICs during field service. 2004 Jul 22 81 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, full pagewidth MSB 31 TDI 28 27 0111000100011000 16-bit part number 12 11 00000010101 11-bit manufacturer identification 1 LSB 0 1 TDO nnnn 4-bit version code MHB734 Fig.45 32 bits of identification code. 11 LIMITING VALUES In accordance with the Absolute Maximum Rating System (IEC 60134); all ground pins connected together and grounded (0 V); all supply pins connected together. SYMBOL VDDD VDDA Vi(A) Vi(n) Vi(D) VSS Tstg Tamb Vesd PARAMETER digital supply voltage analog supply voltage input voltage at analog inputs input voltage at pins XTALI, SDA and SCL input voltage at digital inputs or I/O pins voltage difference between VSSA(n) and VSSD(n) storage temperature ambient temperature electrostatic discharge voltage human body model; note 2 machine model; note 3 Notes 1. Condition for maximum voltage at digital inputs or I/O pins: 3.0 V < VDDD < 3.6 V. 2. Class 2 according to EIA/JESD22-114-B. 3. Class B according to EIA/JESD22-115-A. 12 THERMAL CHARACTERISTICS SYMBOL Rth(j-a) SAF7118EH SAF7118H Note 1. The overall Rth(j-a) value can vary depending on the board layout. To minimize the effective Rth(j-a) all power and ground pins must be connected to the power and ground layers directly. An ample copper area direct under the SAF7118 with a number of through-hole plating, which connect to the ground layer (four-layer board: second layer), can also reduce the effective Rth(j-a). Please do not use any solder-stop varnish under the chip. In addition the usage of soldering glue with a high thermal conductance after curing is recommended. 2004 Jul 22 82 PARAMETER thermal resistance from junction to ambient CONDITIONS in free air 29(1) 25(1) K/W K/W VALUE UNIT outputs in 3-state outputs in 3-state; note 1 CONDITIONS MIN. -0.5 -0.5 -0.5 -0.5 -0.5 -0.5 - -65 -40 - - MAX. +4.6 +4.6 +4.6 VDDD + 0.5 +4.6 +5.5 100 +150 +85 2000 200 UNIT V V V V V V mV C C V V Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 13 CHARACTERISTICS VDDD = 3.0 to 3.6 V; VDDA = 3.1 to 3.5 V; Tamb = -40 to +85 C (typical values measured at Tamb = 25 C); timings and levels refer to drawings and conditions illustrated in Fig.46; unless otherwise specified. SYMBOL Supplies VDDD IDDD PD VDDA IDDA digital supply voltage digital supply current power dissipation digital part analog supply voltage analog supply current AOSL1 and AOSL0 = 0 CVBS mode Y/C mode component mode PA power dissipation analog part CVBS mode Y/C mode component mode Ptot(A+D) total power dissipation analog and digital part CVBS mode Y/C mode component mode - - - - - - - - - - 75 130 250 248 430 825 533 710 1105 5 - - - - - - - - 1350 - mA mA mA mW mW mW mW mW mW mW X port 3-state; 8-bit I port 3.0 - - 3.1 3.3 85 280 3.3 3.6 - - 3.5 V mA mW V PARAMETER CONDITIONS MIN. TYP. MAX. UNIT Ptot(A+D)(pd) total power CE pulled down to ground dissipation analog and digital part in power-down mode total power dissipation analog and digital part in power-save mode Ptot(A+D)(ps) I2C-bus controlled via subaddress - 88H = 0FH 75 - mW Analog part Iclamp Vi(p-p) clamping current input voltage (peak-to-peak value) input impedance input capacitance channel crosstalk fi < 5 MHz VI = 1 V DC for normal video levels 1 V (p-p), -3 dB termination 18/56 and AC coupling required; coupling capacitor is 47 nF clamping current off - - 8 0.7 - - A V Zi Ci cs 200 - - - - - - 10 -50 k pF dB 2004 Jul 22 83 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SYMBOL PARAMETER at -3 dB amplifier plus anti-alias filter bypassed amplifier plus anti-alias filter bypassed CONDITIONS - - - 25.4 - - maximum deviation - 1 x 100 ; ------------------------------------------------- minimum deviation note 1 Digital inputs VIL(SCL,SDA) LOW-level input voltage pins SDA and SCL HIGH-level input voltage pins SDA and SCL LOW-level CMOS input voltage pin XTALI HIGH-level CMOS input voltage pin XTALI LOW-level input voltage all other inputs HIGH-level input voltage all other inputs input leakage current I/O leakage current input capacitance I/O at high-impedance note 2 -0.5 - - MIN. TYP. - - - 28.6 - - - SAF7118 MAX. UNIT 9-bit analog-to-digital converters B diff Gdiff fclk(ADC) LEdc(d) LEdc(i) GADC analog bandwidth differential phase differential gain ADC clock frequency DC differential linearity error DC integral linearity error ADC gain inequality 7 2 2 - 0.7 1 3 MHz deg % MHz LSB LSB % +0.3VDD(I2C) V VIH(SCL,SDA) note 2 0.7VDD(I2C) - VDD(I2C) + 0.5 V VIL(XTALI) -0.3 - +0.8 V VIH(XTALI) 2.0 - VDDD + 0.3 V VIL(n) -0.3 - +0.8 V VIH(n) 2.0 - 5.5 V ILI ILI/O Ci VOL(SDA) VOL(clk) - - - - -0.5 - - - - - 1 10 8 A A pF Digital outputs; note 3 LOW-level output voltage pin SDA LOW-level output voltage for clocks SDA at 3 mA sink current 0.4 +0.6 V V 2004 Jul 22 84 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SYMBOL VOH(clk) VOL(n) PARAMETER HIGH-level output voltage for clocks LOW-level output voltage all other digital outputs HIGH-level output voltage all other digital outputs CONDITIONS MIN. 2.4 0 - - TYP. SAF7118 MAX. VDDD + 0.5 0.4 UNIT V V VOH(n) 2.4 - VDDD + 0.5 V Clock output timing (LLC and LLC2); note 4 CL Tcy output load capacitance cycle time duty factors for tLLCH/tLLC and tLLC2H/tLLC2 rise time LLC and LLC2 fall time LLC and LLC2 delay time between LLC and LLC2 output pin LLC pin LLC2 CL = 40 pF 15 35 70 40 - - - - 50 39 78 60 pF ns ns % tr tf td(LLC-LLC2) 0.2 V to VDDD - 0.2 V VDDD - 0.2 V to 0.2 V measured at 1.5 V; CL = 25 pF - - -4 - - - 5 5 +8 ns ns ns Horizontal PLL fhor(nom) fhor/fhor(nom) nominal line frequency permissible static deviation 50 Hz field 60 Hz field - - - 15625 15734 - - - 5.7 Hz Hz % Subcarrier PLL fsc(nom) nominal subcarrier PAL BGHI frequency NTSC M PAL M PAL N fsc fxtal(nom) fxtal(nom) lock-in range Crystal oscillator for 32.11 MHz; note 5 nominal frequency permissible nominal frequency deviation permissible nominal frequency deviation with temperature - - 32.11 - - 70 x 10-6 MHz - - - - 400 4433619 - 3579545 - 3575612 - 3582056 - - - Hz Hz Hz Hz Hz fxtal(nom)(T) - - 30 x 10-6 2004 Jul 22 85 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SYMBOL PARAMETER CONDITIONS MIN. - - 40 TYP. SAF7118 MAX. UNIT C pF fF pF CRYSTAL SPECIFICATION (X1) Tamb(X1) CL Rs C1 C0 ambient temperature load capacitance series resonance resistor motional capacitance parallel capacitance 0 8 - - - 70 - 80 1.5 20% - 4.3 20% - Crystal oscillator for 24.576 MHz; note 5 fxtal(nom) fxtal(nom) nominal frequency permissible nominal frequency deviation permissible nominal frequency deviation with temperature - - 24.576 - - 50 x 10-6 MHz fxtal(nom)(T) - - 20 x 10-6 CRYSTAL SPECIFICATION (X1) Tamb(X1) CL Rs C1 C0 ambient temperature load capacitance series resonance resistor motional capacitance parallel capacitance 0 8 - - - - - 40 70 - 80 C pF fF pF 1.5 20% - 3.5 20% - Clock input timing (XCLK) Tcy tr tf tSU;DAT tHD;DAT cycle time duty factors for tLLCH/tLLC rise time fall time 31 40 - - 10 6 - 50 - - - - 45 60 5 5 - - ns % ns ns Data and control signal input timing X port, related to XCLK input input data set-up time input data hold time ns ns 2004 Jul 22 86 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SYMBOL PARAMETER CONDITIONS MIN. - - - - - TYP. SAF7118 MAX. UNIT Clock output timing CL Tcy tr tf output load capacitance cycle time duty factors for tXCLKH/tXCLKL rise time fall time 0.6 to 2.6 V 2.6 to 0.6 V 15 35 35 - - 50 39 65 5 5 pF ns % ns ns Data and control signal output timing X port, related to XCLK output (for XPCK[1:0]83H[5:4] = 00 is default); note 4 CL tOHD;DAT tPD output load capacitance output data hold time CL = 15 pF 15 4 - - - - 50 - 19 pF ns ns propagation delay CL = 15 pF from positive edge of XCLK output Control signal output timing RT port, related to LLC output CL tOHD;DAT tPD output load capacitance output hold time CL = 15 pF propagation delay CL = 15 pF from positive edge of LLC output 15 4 - - - - 50 - 19 pF ns ns ICLK output timing CL Tcy tr tf output load capacitance cycle time duty factors for tICLKH/tICLKL rise time fall time 0.6 to 2.6 V 2.6 to 0.6 V 15 31 35 - - - - - - - 50 45 65 5 5 pF ns % ns ns 2004 Jul 22 87 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SYMBOL PARAMETER CONDITIONS MIN. - TYP. SAF7118 MAX. UNIT Data and control signal output timing I port, related to ICLK output (for IPCK[1:0] 87H[5:4] = 00 is default) CL output load capacitance at all outputs output data hold time output delay time CL = 15 pF CL = 15 pF 15 50 pF tOHD;DAT to(d) Tcy Notes 4 - 31 - - - - 19 ns ns ICLK input timing cycle time 100 ns 1. ADC1 is not taken into account, since component video is always converted by ADC2, ADC3 and ADC4. 2. VDD(I2C) is the supply voltage of the I2C-bus. For VDD(I2C) = 3.3 V then VIL(SCL,SDA)(max) = 1 V; for VDD(I2C) = 5 V then VIL(SCL,SDA)(max) = 1.5 V. For VDD(I2C) = 3.3 V then VIH(SCL,SDA)(min) = 2.3 V; for VDD(I2C) = 5 V then VIH(SCL,SDA)(min) = 3.5 V. 3. The levels must be measured with load circuits; 1.2 k at 3 V (TTL load); CL = 50 pF. 4. The effects of rise and fall times are included in the calculation of tOHD;DAT and tPD. Timings and levels refer to drawings and conditions illustrated in Fig.46. 5. The crystal oscillator drive level is typical 0.28 mW. 2004 Jul 22 88 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, full pagewidth Tcy t XCLKH 2.4 V clock input XCLK 1.5 V 0.6 V t SU;DAT t HD;DAT tf tr data and control inputs (X port) 2.0 V not valid 0.8 V t SU;DAT t HD;DAT 2.0 V input XDQ 0.8 V t o(d) t OHD;DAT data and control outputs X port, I port -2.4 V -0.6 V t X(I)CLKH clock outputs LLC, LLC2, XCLK, ICLK and ICLK input t X(I)CLKL -2.6 V -1.5 V -0.6 V tf tr MHB735 Fig.46 Data input/output timing diagram (X port, RT port and I port). 2004 Jul 22 89 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 14 APPLICATION INFORMATION SAF7118 VDDD 680 VDDD or VSSD for crystal strapping 4.7 k VDDD VDDD or VSSD for I2C-bus slave address strapping 150 pF BAT83 FB 680 75 t BF840 boundary scan(1) TRST TDO TDI A5 FSW B5 C6 TCK B6 TMS D6 M12 AMCLK AMXCLK 4.7 k audio clock I2C-bus port SCL INT_A CE N9 P9 N4 RES P5 L10 N10 M10 N5 P4 B11 D8 C7 A6 B7 ALRCLK ASCLK SDA P11 P12 N11 P10 4.7 k DGND 18 (3x) CVBS1 CVBS2 S 56 (3x) 18 (4x) VSB1 VSB2 G YS 56 (4x) 18 (4x) Y1 Y2 B PB 56 (4x) 18 (4x) C1 C2 R PR 56 (4x) 47 nF AI11 AI12 AI13 AI14 AI1D AGND AI21 AI22 AI23 AI24 AI2D M13 J2 K1 K2 L3 K3 C2 G4 G3 H2 J3 H1 RTCO RTS1 RTS0 LLC2 LLC XTRI XRV XRH XRDY XDQ expansion port AD port scaled image port host port real-time XCLK A7 XPD[7:0] C11, A11, B10, A10, B9, A9, B8, A8 AI31 AI32 AI33 AI34 AI3D AGNDA AI41 AI42 AI43 AI44 AI4D E3 F2 F3 G1 F1 L2 B1 D2 D1 E1 D3 M2, J4, H3, E4, C1 M3, K4, H4, F4, D4 L5, L9, J11, F11, D10, D7 SAF7118EH G13, F14, F13, E14, E12, E13, E11, D14 L12 K13 L14 K14 K12 N12 L13 HPD[7:0] ITRI IGP1 IGP0 IGPV IGPH ITRDY IDQ EXMCLR AOUT AOUT P3 M1 L1, J1, G2, E2 M5, M9, J12, F12, C10, C8 L4, L8, L11, G11, D11, D9, D5 M4, M8, M11, H12, D12, C9, C5 ICLK M14 K11, J13, J14, H13, IPD[7:0] H14, H11, G12, G14 CLKEXT N6 P6, M6, L6, N7, P7, ADP[8:0] L7, M7, P8, N8 A4 VSS(xtal) B3 VDD(xtal) A2 A3 B4 AGND VDDA VDDD VSSA0 VDDA0 VDDA1A VSSD2 VSSD4 to to to VSSA4 VDDA4 VDDA4A V SSD6 VSSD8 VSSD10 VSSD12 DGND VDDD2 VDDD4 VDDD6 VDDD8 VDDD10 VDDD12 DGND VSSD1 VSSD3 VSSD5 VSSD7 VSSD9 VSSD11 VSSD13 VDDD1 VDDD3 VDDD5 VDDD7 VDDD9 VDDD11 VDDD13 DGND XTALO XTALI XTOUT 24.576 MHz (3rd harmonic) 10 H 10 F DGND 10 F AGND 2.2 H 100 nF AGND 100 nF 0 100 nF 100 nF 100 nF 100 nF 100 nF DGND 100 nF 10 pF 10 pF 1 nF coa025 (1) For board design without boundary scan implementation this pin should be connected to ground. Fig.47 Application example with 24.576 MHz crystal (HBGA156 package). 2004 Jul 22 90 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 VDDD 680 150 pF BAT83 VDDD or VSSD for crystal strapping 4.7 k VDDD t FB 680 BF840 75 boundary scan(1) TRST TDO TDI 150 FSW 152 147 TCK TMS 148 149 76 AMCLK AMXCLK 4.7 k audio clock I2C-bus port SCL INT_A CE 66 64 44 RES 49 71 70 69 48 46 126 140 141 146 144 VDDD or VSSD for I2C-bus slave address strapping 4.7 k ALRCLK ASCLK SDA 72 75 74 68 DGND 18 (3x) 47 nF 83 27 29 31 34 30 3 19 21 23 26 22 RTCO RTS1 RTS0 LLC2 LLC XTRI XRV XRH XRDY XDQ expansion port AD port scaled image port host port real-time CVBS1 CVBS2 S 56 (3x) 18 (4x) AI11 AI12 AI13 AI14 AI1D AGND AI21 AI22 AI23 AI24 VSB1 VSB2 G YS 56 (4x) 18 (4x) AI2D XCLK 143 XPD[7:0] 127, 128, 130, 131, 134, 135, 138, 139 Y1 Y2 B PB 56 (4x) 18 (4x) AI31 AI32 AI33 AI34 AI3D AGNDA AI41 AI42 AI43 AI44 11 13 15 18 14 35 2 5 7 10 6 38, 28, 20, 12, 4 VSSA0 to VSSA4 AGND 37, 32, 24, 16, 8 VDDA0 to VDDA4 51, 67, 96, 108, 133, 145 VSSD2 VSSD4 VSSD6 VSSD8 VSSD10 VSSD12 SAF7118H 103, 105, 107, 109, 110, 111, 112, 113 86 89 87 90 91 77 85 HPD[7:0] ITRI IGP1 IGP0 IGPV IGPH ITRDY IDQ C1 C2 R PR 56 (4x) AI4D EXMCLR AOUT AOUT 43 36 33, 25, 17, 9 50, 65, 95, 106, 132, 142 VDDD2 VDDD4 VDDD6 VDDD8 VDDD10 VDDD12 DGND 47, 63, 88, 104, 129, 137, 153 VSSD1 VSSD3 VSSD5 VSSD7 VSSD9 VSSD11 VSSD13 45, 59, 73, 101, 114, 136, 151 VDDD1 VDDD3 VDDD5 VDDD7 VDDD9 VDDD11 VDDD13 DGND ICLK 84 92, 93, 94, 97, IPD[7:0] 98, 99, 100, 102 CLKEXT 52 53, 54, 55, 56, 57, ADP[8:0] 58, 60, 61, 62 154 157 158 156 VDD(xtal) VSS(xtal) 155 VDDA1A to VDDA4A XTALO XTALI XTOUT VDDA DGND VDDD 24.576 MHz (3rd harmonic) 10 H 10 F 10 F 2.2 H 100 nF 100 nF 0 100 nF 100 nF 100 nF 100 nF 100 nF 100 nF 10 pF 10 pF mbl757 1 nF DGND AGND AGND DGND (1) For board design without boundary scan implementation this pin should be connected to ground. Fig.48 Application example with 24.576 MHz crystal (QFP160 package). 2004 Jul 22 91 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 SAF7118 B4(155) XTALI 32.11 MHz A3(156) XTALO B4(155) XTALI SAF7118 A3(156) XTALO 32.11 MHz B4(155) XTALI SAF7118 A3(156) XTALO 32.11 MHz 4.7 H 1 nF 15 pF 15 pF 33 pF 33 pF 10 pF 10 pF mbl754 (1a) With 3rd harmonic quartz. Crystal load = 8 pF. (1b) With fundamental quartz. Crystal load = 20 pF. (1c) With fundamental quartz. Crystal load = 8 pF SAF7118 B4(155) XTALI 24.576 MHz A3(156) XTALO B4(155) XTALI SAF7118 A3(156) XTALO 24.576 MHz B4(155) XTALI SAF7118 A3(156) XTALO 24.576 MHz 4.7 H 1 nF 18 pF 18 pF 39 pF 39 pF 15 pF 15 pF mbl755 (2a) With 3rd harmonic quartz. Crystal load = 8 pF. (2b) With fundamental quartz. Crystal load = 20 pF. (2c) With fundamental quartz. Crystal load = 8 pF. SAF7118 B4(155) XTALI 32.11 MHz or 24.576 MHz n.c. G clock A3(156) XTALO B4(155) XTALI SAF7118 A3(156) XTALO Rs mbl756 (3a) With direct clock. (3b) With fundamental quartz and restricted drive level. When Pdrive of the internal oscillator is too high a resistance Rs can be placed in series with the output of the oscillator XTALO. Note: The decreased crystal amplitude results in a lower drive level but on the other hand the jitter performance will decrease. Pin numbers for QFP160 in parenthesis. Fig.49 Oscillator application. 2004 Jul 22 92 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15 I2C-BUS DESCRIPTION The SAF7118 supports the `fast mode' I2C-bus specification extension (data rate up to 400 kbit/s). 15.1 I2C-bus format SAF7118 S SLAVE ADDRESS W ACK-s SUBADDRESS ACK-s DATA data transferred (n bytes + acknowledge) ACK-s P MHB339 a. Write procedure. S Sr SLAVE ADDRESS W SLAVE ADDRESS R ACK-s ACK-s SUBADDRESS DATA ACK-s ACK-m P data transferred (n bytes + acknowledge) MHB340 b. Read procedure (combined). Fig.50 I2C-bus format. Table 36 Description of I2C-bus format CODE S Sr SLAVE ADDRESS W SLAVE ADDRESS R ACK-s ACK-m SUBADDRESS DATA P X Note 1. If pin RTCO strapped to supply voltage via a 3.3 k resistor. START condition repeated START condition `0100 0010' (42H, default) or `0100 0000' (40H; note 1) `0100 0011' (43H, default) or `0100 0001' (41H; note 1) acknowledge generated by the slave acknowledge generated by the master subaddress byte; see Tables 37 and 38 data byte; see Table 38; if more than one byte DATA is transmitted the subaddress pointer is automatically incremented STOP condition read/write control bit (LSB slave address); X = 0, order to write (the circuit is slave receiver); X = 1, order to read (the circuit is slave transmitter) DESCRIPTION 2004 Jul 22 93 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 37 Subaddress description and access SUBADDRESS 00H F0H to FFH Video decoder: 01H to 1FH 01H to 05H 06H to 19H 1AH to 1DH 1EH and 1FH front-end part decoder part reserved video decoder status bytes reserved DESCRIPTION chip version SAF7118 ACCESS (READ/WRITE) read only - read and write read and write - read only - read and write - read and write read and write Component processing and interrupt masking: 20H to 2FH 20H to 22H 23H to 25H 26H to 28H 29H to 2CH 2DH to 2FH Audio clock generation: 30H to 3FH 30H to 3AH 3BH to 3FH audio clock generator reserved read and write - read and write - read only - read and write read and write read and write reserved analog input control reserved component control interrupt mask General purpose VBI data slicer: 40H to 7FH 40H to 5EH 5FH 60H to 62H 63H to 7FH VBI data slicer reserved VBI data slicer status reserved X port, I port and the scaler: 80H to EFH 80H to 8FH 90H to BFH C0H to EFH task independent global settings task A definition task B definition 2004 Jul 22 94 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... Table 38 I2C-bus receiver/transmitter overview 2004 Jul 22 2004 Jul 22 95 95 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION Chip version: register 00H Chip version (read only) SUB ADDR. (HEX) D7 D6 D5 D4 D3 D2 D1 D0 00 ID7 ID6 ID5 ID4 - - - - Video decoder: registers 01H to 1FH FRONT-END PART: REGISTERS 01H TO 05H Increment delay Analog input control 1 Analog input control 2 Analog input control 3 Analog input control 4 01 02 03 04 05 (1) WPOFF FUSE0 HLNRS GAI16 GAI26 GUDL1 MODE5 VBSL GAI15 GAI25 GUDL0 MODE4 CPOFF GAI14 GAI24 IDEL3 MODE3 HOLDG GAI13 GAI23 IDEL2 MODE2 GAFIX GAI12 GAI22 IDEL1 MODE1 GAI28 GAI11 GAI21 IDEL0 MODE0 GAI18 GAI10 GAI20 FUSE1 (1) GAI17 GAI27 DECODER PART: REGISTERS 06H TO 1FH Horizontal sync start Horizontal sync stop Sync control Luminance control Luminance brightness control Luminance contrast control Chrominance saturation control Chrominance hue control Chrominance control 1 Chrominance gain control Chrominance control 2 Mode/delay control RT signal control RT/X port output control Analog/ADC/compatibility control VGATE start, FID change VGATE stop 06 07 08 09 0A 0B 0C 0D 0E 0F 10 11 12 13 14 15 16 HSB7 HSS7 AUFD BYPS DBRI7 DCON7 DSAT7 HUEC7 CDTO ACGC OFFU1 COLO RTSE13 RTCE CM99 VSTA7 VSTO7 HSB6 HSS6 FSEL YCOMB DBRI6 DCON6 DSAT6 HUEC6 CSTD2 CGAIN6 OFFU0 RTP1 RTSE12 XRHS UPTCV VSTA6 VSTO6 HSB5 HSS5 FOET LDEL DBRI5 DCON5 DSAT5 HUEC5 CSTD1 CGAIN5 OFFV1 HDEL1 RTSE11 XRVS1 AOSL1 VSTA5 VSTO5 HSB4 HSS4 HTC1 LUBW DBRI4 DCON4 DSAT4 HUEC4 CSTD0 CGAIN4 OFFV0 HDEL0 RTSE10 XRVS0 AOSL0 VSTA4 VSTO4 HSB3 HSS3 HTC0 LUFI3 DBRI3 DCON3 DSAT3 HUEC3 DCVF CGAIN3 CHBW RTP0 RTSE03 HLSEL XTOUTE VSTA3 VSTO3 HSB2 HSS2 HPLL LUFI2 DBRI2 DCON2 DSAT2 HUEC2 FCTC CGAIN2 LCBW2 YDEL2 RTSE02 OFTS2 AUTO1 VSTA2 VSTO2 HSB1 HSS1 VNOI1 LUFI1 DBRI1 DCON1 DSAT1 HUEC1 AUTO0 CGAIN1 LCBW1 YDEL1 RTSE01 OFTS1 APCK1 VSTA1 VSTO1 HSB0 HSS0 VNOI0 LUFI0 DBRI0 DCON0 DSAT0 HUEC0 CCOMB CGAIN0 LCBW0 YDEL0 RTSE00 Product specification OFTS0 SAF7118 SAF7118 APCK0 VSTA0 VSTO0 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 96 96 Philips Semiconductors SUB ADDR. (HEX) 17 18 19 1A to 1D 1E 1F Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION Miscellaneous, VGATE configuration and MSBs Raw data gain control Raw data offset control Reserved Status byte 1 video decoder (read only) Status byte 2 video decoder (read only) D7 LLCE RAWG7 RAWO7 (1) D6 LLC2E RAWG6 RAWO6 (1) D5 LATY2 RAWG5 RAWO5 (1) D4 LATY1 RAWG4 RAWO4 (1) D3 LATY0 RAWG3 RAWO3 (1) D2 VGPS RAWG2 RAWO2 (1) D1 VSTO8 RAWG1 RAWO1 (1) D0 VSTA8 RAWG0 RAWO0 (1) - INTL HLCK HLVLN SLTCA FIDT GLIMT - GLIMB TYPE3 WIPA COLSTR DCSTD1 COPRO DCSTD0 RDCAP Component processing and interrupt masking part: registers 20H to 2FH Reserved Analog input control 5 Analog input control 6 Analog input control 7 Reserved Component delay Component brightness control Component contrast control Component saturation control Interrupt mask 1 Interrupt mask 2 Interrupt mask 3 20 to 22 23 24 25 26 to 28 29 2A 2B 2C 2D 2E 2F (1) (1) (1) (1) (1) (1) (1) (1) (1) AOSL2 GAI37 GAI47 (1) ADPE GAI36 GAI46 (1) EXCLK GAI35 GAI45 (1) REFA GAI34 GAI44 (1) EXMCE GAI32 GAI42 (1) GAI48 GAI31 GAI41 (1) GAI38 GAI30 GAI40 (1) GAI33 GAI43 (1) FSWE CBRI7 CCON7 CSAT7 (1) (1) FSWI CBRI6 CCON6 CSAT6 (1) FSWDL1 CBRI5 CCON5 CSAT5 (1) (1) FSWDL0 CBRI4 CCON4 CSAT4 MVPSV (1) (1) CMFI CBRI3 CCON3 CSAT3 MPPV (1) CPDL2 CBRI2 CCON2 CSAT2 MCCV (1) CPDL1 CBRI1 CCON1 CSAT1 (1) CPDL0 CBRI0 CCON0 CSAT0 MERROF MRDCAP MHLCK MHLVLN MDCSTD1 MDCSTD0 MCOPRO MINTL MFIDT MTYPE3 MCOLSTR Audio clock generator part: registers 30H to 3FH Audio master clock cycles per field 30 31 32 Reserved Audio master clock nominal increment 33 34 35 36 ACPF7 ACPF15 (1) (1) ACPF6 ACPF14 (1) (1) ACPF5 ACPF13 (1) (1) ACPF4 ACPF12 (1) (1) ACPF3 ACPF11 (1) (1) ACPF2 ACPF10 (1) (1) ACPF1 ACPF9 ACPF17 (1) ACPF0 ACPF8 Product specification ACPF16 (1) SAF7118 SAF7118 ACNI7 ACNI15 (1) ACNI6 ACNI14 (1) ACNI5 ACNI13 ACNI21 ACNI4 ACNI12 ACNI20 ACNI3 ACNI11 ACNI19 ACNI2 ACNI10 ACNI18 ACNI1 ACNI9 ACNI17 ACNI0 ACNI8 ACNI16 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 97 97 Philips Semiconductors SUB ADDR. (HEX) 37 38 39 3A 3B to 3F Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION Reserved Clock ratio AMXCLK to ASCLK Clock ratio ASCLK to ALRCLK Audio clock generator basic setup Reserved D7 (1) (1) (1) (1) D6 (1) (1) (1) (1) D5 (1) D4 (1) D3 (1) D2 (1) D1 (1) D0 (1) SDIV5 LRDIV5 (1) SDIV4 LRDIV4 (1) SDIV3 LRDIV3 APLL (1) SDIV2 LRDIV2 AMVR (1) SDIV1 LRDIV1 LRPH (1) SDIV0 LRDIV0 SCPH (1) (1) (1) (1) (1) General purpose VBI data slicer part: registers 40H to 7FH Slicer control 1 LCR2 to LCR24 (n = 2 to 24) Programmable framing code Horizontal offset for slicer Vertical offset for slicer Field offset and MSBs for horizontal and vertical offset Reserved (for testing) Header and data identification (DID) code control Sliced data identification (SDID) code Reserved Slicer status byte 0 (read only) Slicer status byte 1 (read only) Slicer status byte 2 (read only) Reserved 40 41 to 57 58 59 5A 5B 5C 5D 5E 5F 60 61 62 63 to 7F (1) HAM_N LCRn_6 FC6 HOFF6 VOFF6 RECODE (1) (1) FCE LCRn_5 FC5 HOFF5 VOFF5 (1) HUNT_N LCRn_4 FC4 HOFF4 VOFF4 VOFF8 (1) (1) (1) (1) (1) LCRn_7 FC7 HOFF7 VOFF7 FOFF (1) LCRn_3 FC3 HOFF3 VOFF3 (1) LCRn_2 FC2 HOFF2 VOFF2 HOFF10 (1) LCRn_1 FC1 HOFF1 VOFF1 HOFF9 (1) LCRn_0 FC0 HOFF0 VOFF0 HOFF8 (1) (1) (1) FVREF (1) DID5 SDID5 (1) DID4 SDID4 (1) DID3 SDID3 (1) DID2 SDID2 (1) DID1 SDID1 (1) DID0 SDID0 (1) (1) (1) (1) - - LN3 (1) FC8V - LN2 (1) FC7V F21_N LN1 (1) VPSV LN8 LN0 (1) PPV LN7 DT3 (1) CCV LN6 DT2 (1) - LN5 DT1 (1) - LN4 DT0 (1) X port, I port and the scaler part: registers 80H to EFH Product specification TASK INDEPENDENT GLOBAL SETTINGS: 80H TO 8FH Global control 1 Reserved X port I/O enable and output clock phase control 80 81 and 82 83 (1) (1) SAF7118 SAF7118 SMOD (1) TEB (1) TEA (1) ICKS3 (1) ICKS2 (1) ICKS1 (1) ICKS0 (1) (1) (1) XPCK1 XPCK0 (1) XRQT XPE1 XPE0 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 98 98 Philips Semiconductors SUB ADDR. (HEX) 84 85 86 87 88 89 to 8E 8F Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION I port signal definitions I port signal polarities I port FIFO flag control and arbitration I port I/O enable, output clock and gated clock phase control Power save/ADC port control Reserved Status information scaler part D7 IDG01 ISWP1 VITX1 IPCK3 DOSL1 (1) D6 IDG00 ISWP0 VITX0 IPCK2 DOSL0 (1) D5 IDG11 ILLV IDG02 IPCK1 SWRST (1) D4 IDG10 IG0P IDG12 IPCK0 DPROG (1) D3 IDV1 IG1P FFL1 (1) D2 IDV0 IRVP FFL0 (1) D1 IDH1 IRHP FEL1 IPE1 SLM1 (1) D0 IDH0 IDQP FEL0 IPE0 SLM0 (1) SLM3 (1) (1) (1) XTRI ITRI FFIL FFOV PRDON ERROF FIDSCI FIDSCO TASK A DEFINITION: REGISTERS 90H TO BFH Basic settings and acquisition window definition Task handling control X port formats and configuration X port input reference signal definition I port output formats and configuration Horizontal input window start Horizontal input window length Vertical input window start Vertical input window length Horizontal output window length Vertical output window length 90 91 92 93 94 95 96 97 98 99 9A 9B 9C 9D 9E 9F CONLH CONLV XFDV ICODE XO7 (1) OFIDC HLDFV XFDH I8_16 XO6 (1) FSKP2 SCSRC1 XDV1 FYSK XO5 (1) FSKP1 SCSRC0 XDV0 FOI1 XO4 (1) FSKP0 SCRQE XCODE FOI0 XO3 XO11 XS3 XS11 YO3 YO11 YS3 YS11 XD3 XD11 YD3 YD11 RPTSK FSC2 XDH FSI2 XO2 XO10 XS2 XS10 YO2 YO10 YS2 YS10 XD2 XD10 YD2 YD10 STRC1 FSC1 XDQ FSI1 XO1 XO9 XS1 XS9 YO1 YO9 YS1 YS9 XD1 XD9 YD1 YD9 STRC0 FSC0 XCKS FSI0 XO0 XO8 XS0 XS8 YO0 YO8 YS0 YS8 XD0 XD8 YD0 YD8 XS7 (1) XS6 (1) XS5 (1) XS4 (1) YO7 (1) YO6 (1) YO5 (1) YO4 (1) YS7 (1) YS6 (1) YS5 (1) YS4 (1) XD7 (1) XD6 (1) XD5 (1) XD4 (1) Product specification SAF7118 SAF7118 YD7 (1) YD6 (1) YD5 (1) YD4 (1) This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 99 99 Philips Semiconductors SUB ADDR. (HEX) Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION FIR filtering and prescaling Horizontal prescaling Accumulation length Prescaler DC gain and FIR prefilter control Reserved Luminance brightness control Luminance contrast control Chrominance saturation control Reserved Horizontal phase scaling Horizontal luminance scaling increment Horizontal luminance phase offset Reserved Horizontal chrominance scaling increment Horizontal chrominance phase offset Reserved Vertical scaling Vertical luminance scaling increment Vertical chrominance scaling increment Vertical scaling mode control Reserved Vertical chrominance phase offset `00' D7 D6 D5 D4 D3 D2 D1 D0 A0 A1 A2 A3 A4 A5 A6 A7 (1) (1) (1) (1) XPSC5 XACL5 PFY1 (1) XPSC4 XACL4 PFY0 (1) XPSC3 XACL3 XC2_1 (1) XPSC2 XACL2 XDCG2 (1) XPSC1 XACL1 XDCG1 (1) XPSC0 XACL0 XDCG0 (1) PFUV1 (1) PFUV0 (1) BRIG7 CONT7 SATN7 (1) BRIG6 CONT6 SATN6 (1) BRIG5 CONT5 SATN5 (1) BRIG4 CONT4 SATN4 (1) BRIG3 CONT3 SATN3 (1) BRIG2 CONT2 SATN2 (1) BRIG1 CONT1 SATN1 (1) BRIG0 CONT0 SATN0 (1) A8 A9 AA AB AC AD AE AF XSCY7 (1) XSCY6 (1) XSCY5 (1) XSCY4 XSCY12 XPHY4 (1) XSCY3 XSCY11 XPHY3 (1) XSCY2 XSCY10 XPHY2 (1) XSCY1 XSCY9 XPHY1 (1) XSCY0 XSCY8 XPHY0 (1) XPHY7 (1) XPHY6 (1) XPHY5 (1) XSCC7 (1) XSCC6 (1) XSCC5 (1) XSCC4 XSCC12 XPHC4 (1) XSCC3 XSCC11 XPHC3 (1) XSCC2 XSCC10 XPHC2 (1) XSCC1 XSCC9 XPHC1 (1) XSCC0 XSCC8 XPHC0 (1) XPHC7 (1) XPHC6 (1) XPHC5 (1) B0 B1 B2 B3 B4 B5 to B7 B8 YSCY7 YSCY15 YSCC7 YSCC15 (1) (1) YSCY6 YSCY14 YSCC6 YSCC14 (1) (1) YSCY5 YSCY13 YSCC5 YSCC13 (1) (1) YSCY4 YSCY12 YSCC4 YSCC12 YMIR (1) YSCY3 YSCY11 YSCC3 YSCC11 (1) (1) YSCY2 YSCY10 YSCC2 YSCC10 (1) (1) YSCY1 YSCY9 YSCC1 YSCC9 (1) (1) YSCY0 YSCY8 YSCC0 YSCC8 Product specification SAF7118 SAF7118 YMODE (1) YPC07 YPC06 YPC05 YPC04 YPC03 YPC02 YPC01 YPC00 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 100 100 Philips Semiconductors SUB ADDR. (HEX) B9 BA BB BC BD BE BF Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION Vertical chrominance phase offset `01' Vertical chrominance phase offset `10' Vertical chrominance phase offset `11' Vertical luminance phase offset `00' Vertical luminance phase offset `01' Vertical luminance phase offset `10' Vertical luminance phase offset `11' D7 YPC17 YPC27 YPC37 YPY07 YPY17 YPY27 YPY37 D6 YPC16 YPC26 YPC36 YPY06 YPY16 YPY26 YPY36 D5 YPC15 YPC25 YPC35 YPY05 YPY15 YPY25 YPY35 D4 YPC14 YPC24 YPC34 YPY04 YPY14 YPY24 YPY34 D3 YPC13 YPC23 YPC33 YPY03 YPY13 YPY23 YPY33 D2 YPC12 YPC22 YPC32 YPY02 YPY12 YPY22 YPY32 D1 YPC11 YPC21 YPC31 YPY01 YPY11 YPY21 YPY31 D0 YPC10 YPC20 YPC30 YPY00 YPY10 YPY20 YPY30 TASK B DEFINITION REGISTERS C0H TO EFH Basic settings and acquisition window definition Task handling control X port formats and configuration Input reference signal definition I port formats and configuration Horizontal input window start Horizontal input window length Vertical input window start Vertical input window length Horizontal output window length C0 C1 C2 C3 C4 C5 C6 C7 C8 C9 CA CB CC CD CONLH CONLV XFDV ICODE XO7 (1) OFIDC HLDFV XFDH I8_16 XO6 (1) FSKP2 SCSRC1 XDV1 FYSK XO5 (1) FSKP1 SCSRC0 XDV0 FOI1 XO4 (1) FSKP0 SCRQE XCODE FOI0 XO3 XO11 XS3 XS11 YO3 YO11 YS3 YS11 XD3 XD11 RPTSK FSC2 XDH FSI2 XO2 XO10 XS2 XS10 YO2 YO10 YS2 YS10 XD2 XD10 STRC1 FSC1 XDQ FSI1 XO1 XO9 XS1 XS9 YO1 YO9 YS1 YS9 XD1 XD9 STRC0 FSC0 XCKS FSI0 XO0 XO8 XS0 XS8 YO0 YO8 XS7 (1) XS6 (1) XS5 (1) XS4 (1) YO7 (1) YO6 (1) YO5 (1) YO4 (1) Product specification YS7 (1) YS6 (1) YS5 (1) YS4 (1) YS0 SAF7118 SAF7118 YS8 XD0 XD8 XD7 (1) XD6 (1) XD5 (1) XD4 (1) This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 101 101 Philips Semiconductors SUB ADDR. (HEX) CE CF FIR filtering and prescaling Horizontal prescaling Accumulation length Prescaler DC gain and FIR prefilter control Reserved Luminance brightness control Luminance contrast control Chrominance saturation control Reserved Horizontal phase scaling Horizontal luminance scaling increment Horizontal luminance phase offset Reserved Horizontal chrominance scaling increment Horizontal chrominance phase offset Reserved Vertical scaling Vertical luminance scaling increment Vertical chrominance scaling increment Vertical scaling mode control Reserved E0 E1 E2 E3 E4 E5 to E7 YSCY7 YSCY15 YSCC7 YSCC15 (1) (1) Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION Vertical output window length D7 YD7 (1) D6 YD6 (1) D5 YD5 (1) D4 YD4 (1) D3 YD3 YD11 D2 YD2 YD10 D1 YD1 YD9 D0 YD0 YD8 D0 D1 D2 D3 D4 D5 D6 D7 (1) (1) (1) (1) XPSC5 XACL5 PFY1 (1) XPSC4 XACL4 PFY0 (1) XPSC3 XACL3 XC2_1 (1) XPSC2 XACL2 XDCG2 (1) XPSC1 XACL1 XDCG1 (1) XPSC0 XACL0 XDCG0 (1) PFUV1 (1) PFUV0 (1) BRIG7 CONT7 SATN7 (1) BRIG6 CONT6 SATN6 (1) BRIG5 CONT5 SATN5 (1) BRIG4 CONT4 SATN4 (1) BRIG3 CONT3 SATN3 (1) BRIG2 CONT2 SATN2 (1) BRIG1 CONT1 SATN1 (1) BRIG0 CONT0 SATN0 (1) D8 D9 DA DB DC DD DE DF XSCY7 (1) XSCY6 (1) XSCY5 (1) XSCY4 XSCY12 XPHY4 (1) XSCY3 XSCY11 XPHY3 (1) XSCY2 XSCY10 XPHY2 (1) XSCY1 XSCY9 XPHY1 (1) XSCY0 XSCY8 XPHY0 (1) XPHY7 (1) XPHY6 (1) XPHY5 (1) XSCC7 (1) XSCC6 (1) XSCC5 (1) XSCC4 XSCC12 XPHC4 (1) XSCC3 XSCC11 XPHC3 (1) XSCC2 XSCC10 XPHC2 (1) XSCC1 XSCC9 XPHC1 (1) XSCC0 XSCC8 XPHC0 (1) XPHC7 (1) XPHC6 (1) XPHC5 (1) YSCY6 YSCY14 YSCC6 YSCC14 (1) (1) YSCY5 YSCY13 YSCC5 YSCC13 (1) (1) YSCY4 YSCY12 YSCC4 YSCC12 YMIR (1) YSCY3 YSCY11 YSCC3 YSCC11 (1) (1) YSCY2 YSCY10 YSCC2 YSCC10 (1) (1) YSCY1 YSCY9 YSCC1 YSCC9 (1) (1) YSCY0 YSCY8 Product specification SAF7118 SAF7118 YSCC0 YSCC8 YMODE (1) This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 2004 Jul 22 2004 Jul 22 102 102 Philips Semiconductors SUB ADDR. (HEX) E8 E9 EA EB EC ED EE EF Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input REGISTER FUNCTION Vertical chrominance phase offset `00' Vertical chrominance phase offset `01' Vertical chrominance phase offset `10' Vertical chrominance phase offset `11' Vertical luminance phase offset `00' Vertical luminance phase offset `01' Vertical luminance phase offset `10' Vertical luminance phase offset `11' Note D7 YPC07 YPC17 YPC27 YPC37 YPY07 YPY17 YPY27 YPY37 D6 YPC06 YPC16 YPC26 YPC36 YPY06 YPY16 YPY26 YPY36 D5 YPC05 YPC15 YPC25 YPC35 YPY05 YPY15 YPY25 YPY35 D4 YPC04 YPC14 YPC24 YPC34 YPY04 YPY14 YPY24 YPY34 D3 YPC03 YPC13 YPC23 YPC33 YPY03 YPY13 YPY23 YPY33 D2 YPC02 YPC12 YPC22 YPC32 YPY02 YPY12 YPY22 YPY32 D1 YPC01 YPC11 YPC21 YPC31 YPY01 YPY11 YPY21 YPY31 D0 YPC00 YPC10 YPC20 YPC30 YPY00 YPY10 YPY20 YPY30 1. All unused control bits must be programmed with logic 0 to ensure compatibility to future enhancements. Product specification SAF7118 SAF7118 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2 15.2.1 I2C-bus details SUBADDRESS 00H SAF7118 Table 39 Chip Version (CV) identification; 00H[7:4]; read only register LOGIC LEVELS FUNCTION ID7 Chip Version (CV) 15.2.2 SUBADDRESS 01H CV3 ID6 CV2 ID5 CV1 ID4 CV0 The programming of the horizontal increment delay is used to match internal processing delays to the delay of the ADC. Use recommended position only. Table 40 Horizontal increment delay; 01H[6:0] BIT D6 DESCRIPTION white peak control off SYMBOL WPOFF(1) VALUE 0 FUNCTION white peak control active (AD signal is attenuated, if nominal luminance output white level is exceeded) white peak control disabled off 1 LSB 2 LSB 3 LSB no update minimum delay recommended position maximum delay 1 D[5:4] update hysteresis for 9-bit gain; see Fig.9 GUDL[1:0] 00 01 10 11 D[3:0] increment delay IDEL[3:0] 1111 1110 0111 0000 Note 1. HLNRS = 1 should not be used in combination with WPOFF = 0. 2004 Jul 22 103 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.3 SUBADDRESS 02H SAF7118 Table 41 Analog input control 1 (AICO1); 02H[7:0]; note 1 BIT DESCRIPTION SYMBOL FUSE[1:0] VALUE 00 01 10 11 CVBS modes 1 D[5:0] mode selection MODE[5:0] 000000 000001 000010 000011 000100 000101 Y + C modes 1 D[5:0] mode selection MODE[5:0] 000110 Mode 06: Y (automatic gain) from AI11 + C (gain adjustable via GAI28 to GAI20) from AI21; note 2; see Fig.57 Mode 07: Y (automatic gain) from AI12 + C (gain adjustable via GAI28 to GAI20) from AI22; note 2; see Fig.58 Mode 08: Y (automatic gain) from AI11 + C (gain adapted to Y gain) from AI21; note 2; see Fig.59 Mode 09: Y (automatic gain) from AI12 + C (gain adapted to Y gain) from AI22; note 2; see Fig.60 Mode 0A: Y (automatic gain) from AI13 + C (gain adjustable via GAI28 to GAI20) from AI23; note 2; see Fig.61 Mode 0B: Y (automatic gain) from AI14 + C (gain adjustable via GAI28 to GAI20) from AI24; note 2; see Fig.62 Mode 0C: Y (automatic gain) from AI13 + C (gain adapted to Y gain) from AI23; note 2; see Fig.63 Mode 0D: Y (automatic gain) from AI14 + C (gain adapted to Y gain) from AI24; note 2; see Fig.64 Mode 00: CVBS (automatic gain) from AI11; see Fig.51 Mode 01: CVBS (automatic gain) from AI12; see Fig.52 Mode 02: CVBS (automatic gain) from AI21; see Fig.53 Mode 03: CVBS (automatic gain) from AI22; see Fig.54 Mode 04: CVBS (automatic gain) from AI23; see Fig.55 Mode 05: CVBS (automatic gain) from AI24; see Fig.56 amplifier active amplifier plus anti-alias filter active FUNCTION amplifier plus anti-alias filter bypassed D[7:6] analog function select; see Figs 4 and 8 000111 001000 001001 001010 001011 001100 001101 2004 Jul 22 104 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input BIT DESCRIPTION SYMBOL VALUE FUNCTION SAF7118 CVBS modes 2 D[5:0] mode selection MODE[5:0] 001110 001111 010000 010001 010010 010011 010100 010101 Y + C modes 2 D[5:0] mode selection MODE[5:0] 010110 Mode 16: Y (automatic gain) from AI31 + C (gain adjustable via GAI28 to GAI20) from AI41; note 2; see Fig.73 Mode 17: Y (automatic gain) from AI32 + C (gain adjustable via GAI28 to GAI20) from AI42; note 2; see Fig.74 Mode 18: Y (automatic gain) from AI31 + C (gain adapted to Y gain) from AI41; note 2; see Fig.75 Mode 19: Y (automatic gain) from AI32 + C (gain adapted to Y gain) from AI42; note 2; see Fig.76 Mode 1A: Y (automatic gain) from AI33 + C (gain adjustable via GAI28 to GAI20) from AI43; note 2; see Fig.77 Mode 1B: Y (automatic gain) from AI34 + C (gain adjustable via GAI28 to GAI20) from AI44; note 2; see Fig.78 Mode 1C: Y (automatic gain) from AI33 + C (gain adapted to Y gain) from AI43; note 2; see Fig.79 Mode 1D: Y (automatic gain) from AI34 + C (gain adapted to Y gain) from AI44; note 2; see Fig.80 Mode 0E: CVBS (automatic gain) from AI13; see Fig.65 Mode 0F: CVBS (automatic gain) from AI14; see Fig.66 Mode 10: CVBS (automatic gain) from AI31; see Fig.67 Mode 11: CVBS (automatic gain) from AI32; see Fig.68 Mode 12: CVBS (automatic gain) from AI41; see Fig.69 Mode 13: CVBS (automatic gain) from AI42; see Fig.70 Mode 14: CVBS (automatic gain) from AI43; see Fig.71 Mode 15: CVBS (automatic gain) from AI44; see Fig.72 010111 011000 011001 011010 011011 011100 011101 CVBS modes 3 D[5:0] mode selection MODE[5:0] Y-PB-PR modes D[5:0] mode selection MODE[5:0] 100000 100001 011110 011111 Mode 1E: CVBS (automatic gain) from AI33; see Fig.81 Mode 1F: CVBS (automatic gain) from AI34; see Fig.82 Mode 20: SY-PB-PR (automatic gain for sync channel only) from AI11, AI21, AI31, AI41; see Fig.83 Mode 21: SY-PB-PR (automatic gain for sync channel only) from AI12, AI22, AI32, AI42; see Fig.84 Mode 2E: SY-PB-PR (automatic gain for sync channel only) from AI13, AI23, AI33, AI43; see Fig.85 Mode 2F: SY-PB-PR (automatic gain for sync channel only) from AI14, AI24, AI34, AI44; see Fig.86 105 100010 to 101101 reserved 101110 101110 2004 Jul 22 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input BIT DESCRIPTION SYMBOL VALUE FUNCTION SAF7118 RGB modes D[5:0] mode selection MODE[5:0] 110000 110001 Mode 30: SRGB (automatic gain for sync channel only) from AI11, AI21, AI31, AI41; see Fig.87 Mode 31: SRGB (automatic gain for sync channel only) from AI12, AI22, AI32, AI42; see Fig.88 Mode 3E: SRGB (automatic gain for sync channel only) from AI13, AI23, AI33, AI43; see Fig.89 Mode 3F: SRGB (automatic gain for sync channel only) from AI14, AI24, AI34, AI44; see Fig.90 110010 to 111101 reserved 111110 111111 VSB modes; see Fig.91 D[5:0] mode selection MODE[5:0] 000000 000001 001110 001111 000010 000011 000100 000101 010000 010001 011110 011111 010010 010011 010100 010101 Notes 1. Always refer to Table 71, usage of bits FSWE and FSWI. 2. To take full advantage of the Y/C modes 06 to 0D and 16 to 1D the I2C-bus bit BYPS (subaddress 09H, bit D7) should be set to logic 1 (full luminance bandwidth). Mode 00: input AI11; REFA = 1, DOSL = 0, GAFIX = 1 Mode 01: input AI12; REFA = 1, DOSL = 0, GAFIX = 1 Mode 0E: input AI13; REFA = 1, DOSL = 0, GAFIX = 1 Mode 0F: input AI14; REFA = 1, DOSL = 0, GAFIX = 1 Mode 02: input AI21; REFA = 1, DOSL = 1, GAFIX = 1 Mode 03: input AI22; REFA = 1, DOSL = 1, GAFIX = 1 Mode 04: input AI23; REFA = 1, DOSL = 1, GAFIX = 1 Mode 05: input AI24; REFA = 1, DOSL = 1, GAFIX = 1 Mode 10: input AI31; REFA = 1, DOSL = 2, GAFIX = 1 Mode 11: input AI32; REFA = 1, DOSL = 2, GAFIX = 1 Mode 1E: input AI33; REFA = 1, DOSL = 2, GAFIX = 1 Mode 1F: input AI34; REFA = 1, DOSL = 2, GAFIX = 1 Mode 12: input AI41; REFA = 1, DOSL = 3, GAFIX = 1 Mode 13: input AI42; REFA = 1, DOSL = 3, GAFIX = 1 Mode 14: input AI43; REFA = 1, DOSL = 3, GAFIX = 1 Mode 15: input AI44; REFA = 1, DOSL = 3, GAFIX = 1 2004 Jul 22 106 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB738 AD4 MUX R MHB739 Fig.51 MODE00 CVBS1. Fig.52 MODE01 CVBS2. handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB740 AD4 MUX R MHB741 Fig.53 MODE02 CVBS3. Fig.54 MODE03 CVBS4. 2004 Jul 22 107 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB742 AD4 MUX R MHB743 Fig.55 MODE04 CVBS5. Fig.56 MODE05 CVBS6. handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB744 AD4 MUX R MHB745 Fig.57 MODE06 YC1 (gain -> GAI2 level). Fig.58 MODE07 YC2 (gain -> GAI2 level). 2004 Jul 22 108 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB746 AD4 MUX R MHB747 Fig.59 MODE08 YC1 (gain adapted to Y gain). Fig.60 MODE09 YC2 (gain adapted to Y gain). handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB748 AD4 MUX R MHB749 Fig.61 MODE0A YC3 (gain -> GAI2 level). Fig.62 MODE0B YC4 (gain -> GAI2 level). 2004 Jul 22 109 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB750 AD4 MUX R MHB751 Fig.63 MODE0C YC3 (gain adapted to Y gain). Fig.64 MODE0D YC4 (gain adapted to Y gain). handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB752 AD4 MUX R MHB753 Fig.65 MODE0E CVBS7. Fig.66 MODE0F CVBS8. 2004 Jul 22 110 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB754 AD4 MUX R MHB755 Fig.67 MODE10 CVBS9. Fig.68 MODE11 CVBS10. handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB756 AD4 MUX R MHB757 Fig.69 MODE12 CVBS11. Fig.70 MODE13 CVBS12. 2004 Jul 22 111 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB758 AD4 MUX R MHB759 Fig.71 MODE14 CVBS13. Fig.72 MODE15 CVBS14. handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB760 AD4 MUX R MHB761 Fig.73 MODE16 YC5 (gain -> GAI2 level). Fig.74 MODE17 YC6 (gain -> GAI2 level). 2004 Jul 22 112 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB762 AD4 MUX R MHB763 Fig.75 MODE18 YC5 (gain adapted to Y gain). Fig.76 MODE19 YC6 (gain adapted to Y gain). handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB764 AD4 MUX R MHB765 Fig.77 MODE1A YC7 (gain -> GAI2 level). Fig.78 MODE1B YC8 (gain -> GAI2 level). 2004 Jul 22 113 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB766 AD4 MUX R MHB767 Fig.79 MODE1C YC7 (gain adapted to Y gain). Fig.80 MODE1D YC8 (gain adapted to Y gain). handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 LUMA CHROMA AD2 CHROMA AD2 G AD3 B G AD3 B AD4 MUX R MHB768 AD4 MUX R MHB769 Fig.81 MODE1E CVBS15. Fig.82 MODE1F CVBS16. 2004 Jul 22 114 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) (CHROMA) AD2 (CHROMA) AD2 Y AD3 CB Y AD3 CB AD4 MUX CR MHB770 AD4 MUX CR MHB771 Fig.83 MODE20 SY-PB-PR1. Fig.84 MODE21 SY-PB-PR2. handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) (CHROMA) AD2 (CHROMA) AD2 Y AD3 CB Y AD3 CB AD4 MUX CR MHB772 AD4 MUX CR MHB773 Fig.85 MODE2E SY-PB-PR3. Fig.86 MODE2F SY-PB-PR4. 2004 Jul 22 115 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) (CHROMA) AD2 (CHROMA) AD2 G AD3 B G AD3 B AD4 MUX R MHB774 AD4 MUX R MHB775 Fig.87 MODE30 SRGB1. Fig.88 MODE31 SRGB2. handbook, halfpage AI11 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 SYNC (LUMA) (CHROMA) AD2 (CHROMA) AD2 G AD3 B G AD3 B AD4 MUX R MHB776 AD4 MUX R MHB777 Fig.89 MODE3E SRGB3. Fig.90 MODE3F SRGB4. 2004 Jul 22 116 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 handbook, halfpage AI11 AI12 AI13 AI14 AI21 AI22 AI23 AI24 AI31 AI32 AI33 AI34 AI41 AI42 AI43 AI44 AD1 ADP [8:0] AD2 AD3 AD4 MUX DOSL [1:0] MHB778 Fig.91 VSB MODES (use CVBS modes with REFA = 1, DOSL = 0 to 3 and GAFIX = 1). 2004 Jul 22 117 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.4 SUBADDRESS 03H SAF7118 Table 42 Analog input control 2 (AICO2); 03H[6:0] BIT DESCRIPTION SYMBOL VALUE HLNRS VBSL 0 1 D5 AGC hold during vertical blanking period 0 1 FUNCTION normal clamping if decoder is in unlocked state reference select if decoder is in unlocked state short vertical blanking (AGC disabled during equalization and serration pulses); recommended setting long vertical blanking (AGC disabled from start of pre-equalization pulses until start of active video (line 22 for 60 Hz, line 24 for 50 Hz) colour peak control active (AD signal is attenuated, if maximum input level is exceeded, avoids clipping effects on screen) colour peak off AGC active AGC integration hold (freeze) automatic gain controlled by MODE5 to MODE0 gain is user programmable via GAI[17:10] and GAI[27:20] see Table 44 see Table 43 D6 HL not reference select D4 colour peak off CPOFF 0 1 D3 automatic gain control integration D2 gain control fix D1 static gain control channel 2 sign bit D0 static gain control channel 1 sign bit 15.2.5 SUBADDRESS 04H HOLDG GAFIX GAI28 GAI18 0 1 0 1 Table 43 Analog input control 3 (AICO3): static gain control channel 1; 03H[0] and 04H[7:0] DECIMAL VALUE 0... ...144 145... ...511 15.2.6 GAIN (dB) -3 0 0 +6 SIGN BIT 03H[0] GAI18 0 0 0 1 GAI17 0 1 1 1 GAI16 0 0 0 1 CONTROL BITS D7 TO D0 GAI15 0 0 0 1 GAI14 0 1 1 1 GAI13 0 0 0 1 GAI12 0 0 0 1 GAI11 0 0 0 1 GAI10 0 0 1 1 SUBADDRESS 05H Table 44 Analog input control 4 (AICO4); static gain control channel 2; 03H[1] and 05H[7:0] DECIMAL VALUE 0... ...144 145... ...511 GAIN (dB) -3 0 0 +6 SIGN BIT 03H[1] GAI28 0 0 0 1 GAI27 0 1 1 1 GAI26 0 0 0 1 CONTROL BITS D7 TO D0 GAI25 0 0 0 1 GAI24 0 1 1 1 GAI23 0 0 0 1 GAI22 0 0 0 1 GAI21 0 0 0 1 GAI20 0 0 1 1 2004 Jul 22 118 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.7 SUBADDRESS 06H SAF7118 Table 45 Horizontal sync start; 06H[7:0] DELAY TIME (STEP SIZE = 8/LLC) -128...-109 (50 Hz) -128...-108 (60 Hz) -108 (50 Hz)... -107 (60 Hz)... ...108 (50 Hz) ...107 (60 Hz) 109...127 (50 Hz) 108...127 (60 Hz) 15.2.8 SUBADDRESS 07H 1 1 0 0 0 0 1 1 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 0 0 0 0 1 0 1 0 1 CONTROL BITS D7 TO D0 HSB7 HSB6 HSB5 HSB4 HSB3 HSB2 HSB1 HSB0 forbidden (outside available central counter range) forbidden (outside available central counter range) Table 46 Horizontal sync stop; 07H[7:0] DELAY TIME (STEP SIZE = 8/LLC) -128...-109 (50 Hz) -128...-108 (60 Hz) -108 (50 Hz)... -107 (60 Hz)... ...108 (50 Hz) ...107 (60 Hz) 109...127 (50 Hz) 108...127 (60 Hz) 1 1 0 0 0 0 1 1 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 0 0 0 0 1 0 1 0 1 CONTROL BITS D7 TO D0 HSS7 HSS6 HSS5 HSS4 HSS3 HSS2 HSS1 HSS0 forbidden (outside available central counter range) forbidden (outside available central counter range) 2004 Jul 22 119 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.9 SUBADDRESS 08H SAF7118 Table 47 Sync control; 08H[7:0] BIT D7 D6 D5 DESCRIPTION automatic field detection field selection; active if AUFD = 0 forced ODD/EVEN toggle SYMBOL VALUE AUFD FSEL FOET 0 1 0 1 0 1 D[4:3] horizontal time constant selection HTC[1:0] 00 01 10 11 D2 horizontal PLL HPLL VNOI[1:0] 0 1 D[1:0] vertical noise reduction 00 01 10 11 FUNCTION field state directly controlled via FSEL automatic field detection; recommended setting 50 Hz, 625 lines 60 Hz, 525 lines ODD/EVEN signal toggles only with interlaced source ODD/EVEN signal toggles fieldwise even if source is non-interlaced TV mode, recommended for poor quality TV signals only; do not use for new applications VTR mode, recommended if a deflection control circuit is directly connected to the SAF7118 reserved fast locking mode; recommended setting PLL closed PLL open; horizontal frequency fixed normal mode; recommended setting fast mode, applicable for stable sources only; automatic field detection (AUFD) must be disabled free running mode vertical noise reduction bypassed 2004 Jul 22 120 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.10 SUBADDRESS 09H Table 48 Luminance control; 09H[7:0] BIT D7 DESCRIPTION chrominance trap/comb filter bypass SYMBOL VALUE BYPS 0 1 D6 D5 adaptive luminance comb filter processing delay in non comb filter mode YCOMB LDEL 0 1 0 1 D4 remodulation bandwidth for luminance; see Figs 14 to 17 LUBW 0 1 D[3:0] sharpness control, luminance filter characteristic; see Fig.18 LUFI[3:0] 0001 0010 0011 0100 0101 0110 0111 0000 1000 1001 1010 1011 1100 1101 1110 1111 15.2.11 SUBADDRESS 0AH Table 49 Luminance brightness control: decoder part; 0AH[7:0] CONTROL BITS D7 TO D0 OFFSET DBRI7 255 (bright) 128 (ITU level) 0 (dark) 1 1 0 DBRI6 1 0 0 DBRI5 1 0 0 DBRI4 1 0 0 DBRI3 1 0 0 DBRI2 1 0 0 FUNCTION SAF7118 chrominance trap or luminance comb filter active; default for CVBS mode chrominance trap or luminance comb filter bypassed; default for S-video mode disabled (= chrominance trap enabled, if BYPS = 0) active, if BYPS = 0 processing delay is equal to internal pipelining delay; recommended setting one (NTSC standards) or two (PAL standards) video lines additional processing delay small remodulation bandwidth (narrow chroma notch higher luminance bandwidth) large remodulation bandwidth (wider chroma notch smaller luminance bandwidth) resolution enhancement filter 8.0 dB at 4.1 MHz resolution enhancement filter 6.8 dB at 4.1 MHz resolution enhancement filter 5.1 dB at 4.1 MHz resolution enhancement filter 4.1 dB at 4.1 MHz resolution enhancement filter 3.0 dB at 4.1 MHz resolution enhancement filter 2.3 dB at 4.1 MHz resolution enhancement filter 1.6 dB at 4.1 MHz plain low-pass filter 2 dB at 4.1 MHz low-pass filter 3 dB at 4.1 MHz low-pass filter 3 dB at 3.3 MHz; 4 dB at 4.1 MHz low-pass filter 3 dB at 2.6 MHz; 8 dB at 4.1 MHz low-pass filter 3 dB at 2.4 MHz; 14 dB at 4.1 MHz low-pass filter 3 dB at 2.2 MHz; notch at 3.4 MHz low-pass filter 3 dB at 1.9 MHz; notch at 3.0 MHz low-pass filter 3 dB at 1.7 MHz; notch at 2.5 MHz DBRI1 1 0 0 DBRI0 1 0 0 2004 Jul 22 121 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.12 SUBADDRESS 0BH Table 50 Luminance contrast control: decoder part; 0BH[7:0] CONTROL BITS D7 TO D0 GAIN DCON7 1.984 (maximum) 1.063 (ITU level) 1.0 0 (luminance off) -1 (inverse luminance) -2 (inverse luminance) 15.2.13 SUBADDRESS 0CH Table 51 Chrominance saturation control: decoder part; 0CH[7:0] CONTROL BITS D7 TO D0 GAIN DSAT7 1.984 (maximum) 1.0 (ITU level) 0 (colour off) -1 (inverse chrominance) -2 (inverse chrominance) 15.2.14 SUBADDRESS 0DH Table 52 Chrominance hue control; 0DH[7:0] CONTROL BITS D7 TO D0 HUE PHASE (DEG) HUEC7 +178.6... ...0... ...-180 0 0 1 HUEC6 1 0 0 HUEC5 1 0 0 HUEC4 1 0 0 HUEC3 1 0 0 HUEC2 1 0 0 0 0 0 1 1 DSAT6 1 1 0 1 0 DSAT5 1 0 0 0 0 DSAT4 1 0 0 0 0 DSAT3 1 0 0 0 0 DSAT2 1 0 0 0 0 0 0 0 0 1 1 DCON6 1 1 1 0 1 0 DCON5 1 0 0 0 0 0 DCON4 1 0 0 0 0 0 DCON3 1 0 0 0 0 0 DCON2 1 1 0 0 0 0 SAF7118 DCON1 1 0 0 0 0 0 DCON0 1 0 0 0 0 0 DSAT1 1 0 0 0 0 DSAT0 1 0 0 0 0 HUEC1 1 0 0 HUEC0 1 0 0 2004 Jul 22 122 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.15 SUBADDRESS 0EH Table 53 Chrominance control 1; 0EH[7:0] FUNCTION BIT D7 DESCRIPTION clear DTO SYMBOL CDTO VALUE 50 Hz/625 LINES 0 1 disabled SAF7118 60 Hz/525 LINES Every time CDTO is set, the internal subcarrier DTO phase is reset to 0 and the RTCO output generates a logic 0 at time slot 68 (see document "RTC Functional Description", available on request). So an identical subcarrier phase can be generated by an external device (e.g. an encoder); if a DTO reset is programmed via CDTO it has always to be executed in the following way: 1. Set CDTO = 0 2. Set CDTO = 1. D[6:4] colour standard selection in non AUTO mode CSTD[2:0] 000 001 010 011 100 101 110 111 PAL BGDHI (4.43 MHz) NTSC M (3.58 MHz) NTSC 4.43 (50 Hz) Combination-PAL N (3.58 MHz) NTSC N (3.58 MHz) reserved SECAM PAL 4.43 (60 Hz) NTSC 4.43 (60 Hz) PAL M (3.58 MHz) NTSC-Japan (3.58 MHz) reserved reserved; do not use reserved; do not use preferred standard(1) is preferred standard(1) is PAL BGDHI (4.43 MHz) NTSC M (3.58 MHz) reserved; do not use reserved; do not use reserved; do not use preferred standard(1) is preferred standard(1) is PAL BGDHI (4.43 MHz) NTSC-Japan (3.58 MHz, no 7.5 IRE offset) preferred standard(1) is SECAM preferred standard(1) is NTSC M (3.58 MHz) D[6:4] colour standard selection in AUTO mode (AUTO mode is selected, if either AUTO0 or AUTO1 is set; see below) CSTD[2:0] 000 001 010 011 100 101 110 111 D3 disable chrominance vertical filter and PAL phase error correction fast colour time constant DCVF 0 1 FCTC 0 1 reserved; do not use reserved; do not use chrominance vertical filter and PAL phase error correction on (during active video lines) chrominance vertical filter and PAL phase error correction permanently off nominal time constant fast time constant for special applications (high quality input source, fast chroma lock required, automatic standard detection off) D2 2004 Jul 22 123 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input FUNCTION BIT DESCRIPTION SYMBOL VALUE 50 Hz/625 LINES 14H[2] automatic chrominance AUTO[1:0] and standard detection control 0EH[1] 00 01 disabled SAF7118 60 Hz/525 LINES active, filter settings and sharpness control are preset to default values according to the detected standard and mode; recommended setting active, filter settings are preset to default values according to the detected standard and mode active, but no filter presets disabled active 10 11 D0 adaptive chrominance comb filter CCOMB 0 1 Note 1. The meaning of `preferred standard' is, that the internal search machine will always give priority to the selected standard, thus the recognition time for these standards is kept short. 15.2.16 SUBADDRESS 0FH Table 54 Chrominance gain control; 0FH[7:0] BIT D7 DESCRIPTION automatic chrominance gain control SYMBOL ACGC VALUE 0 1 FUNCTION on; recommended setting programmable gain via CGAIN6 to CGAIN0; need to be set for SECAM standard D[6:0] chrominance gain value (if ACGC is set to logic 1) CGAIN[6:0] 000 0000 minimum gain (0.5) 010 0100 nominal gain (1.125) 111 1111 maximum gain (7.5) 2004 Jul 22 124 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.17 SUBADDRESS 10H Table 55 Chrominance control 2; 10H[7:0] BIT DESCRIPTION SYMBOL OFFU[1:0] VALUE 00 01 10 11 D[5:4] fine offset adjustment R - Y component OFFV[1:0] 00 01 10 11 D3 chrominance bandwidth; see Figs 12 and 13 CHBW LCBW[2:0] 0 1 D[2:0] combined luminance/chrominance bandwidth adjustment; see Figs 12 to 18 000 0 LSB 1 1 3 1 1 3 4 2 4 SAF7118 FUNCTION LSB LSB LSB LSB LSB LSB D[7:6] fine offset adjustment B - Y component 0 LSB 4 2 4 small wide smallest chrominance bandwidth/largest luminance bandwidth ... to ... largest chrominance bandwidth/smallest luminance bandwidth ... 111 15.2.18 SUBADDRESS 11H Table 56 Mode/delay control; 11H[7:0] BIT D7 colour on DESCRIPTION SYMBOL COLO VALUE 0 1 D6 polarity of RTS1 output signal RTP1 HDEL[1:0] 0 1 D[5:4] fine position of HS (steps in 2/LLC) 00 01 10 11 D3 polarity of RTS0 output signal RTP0 YDEL[2:0] 0 1 D[2:0] luminance delay compensation (steps in 2/LLC) 100 000 011 FUNCTION automatic colour killer enabled; recommended setting colour forced on non-inverted inverted 0 1 2 3 non-inverted inverted -4... ...0... ...3 2004 Jul 22 125 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.19 SUBADDRESS 12H Table 57 RT signal control: RTS0 output; 12H[3:0] The polarity of any signal on RTS0 can be inverted via RTP0[11H[3]]. RTS0 OUTPUT 3-state Constant LOW CREF (13.5 MHz toggling pulse; see Fig.30) CREF2 (6.75 MHz toggling pulse; see Fig.30) HL; horizontal lock indicator (note 1): HL = 0: unlocked HL = 1: locked VL; vertical and horizontal lock: VL = 0: unlocked VL = 1: locked DL; vertical and horizontal lock and colour detected: DL = 0: unlocked DL = 1: locked Reserved HREF, horizontal reference signal; indicates 720 pixels valid data on the expansion port. The positive slope marks the beginning of a new active line. HREF is also generated during the vertical blanking interval (see Fig.30). HS: programmable width in LLC8 steps via HSB[7:0] 06H[7:0] and HSS[7:0] 07H[7:0] fine position adjustment in LLC2 steps via HDEL[1:0] 11H[5:4] (see Fig.30) HQ; HREF gated with VGATE Reserved V123; vertical sync (see vertical timing diagrams Figs 28 and 29) VGATE; programmable via VSTA[8:0] 17H[0] 15H[7:0], VSTO[8:0] 17H[1] 16H[7:0] and VGPS[17H[2]] LSBs of the 9-bit ADC's FID; position programmable via VSTA[8:0] 17H[0] 15H[7:0]; see vertical timing diagrams Figs 28 and 29 Note 1. Function of HL is selectable via HLSEL[13H[3]]: a) HLSEL = 0: HL is standard horizontal lock indicator. 1 1 1 1 1 1 0 0 1 1 1 1 0 1 1 0 0 1 0 1 SAF7118 RTSE03 RTSE02 RTSE01 RTSE00 0 0 0 0 0 0 0 0 0 1 0 0 1 1 0 0 1 0 1 0 0 1 1 0 1 0 1 0 1 0 0 1 1 1 0 0 1 1 0 1 0 1 0 1 b) HLSEL = 1: HL is fast horizontal lock indicator (use is not recommended for sources with unstable timebase e.g. VCRs). 2004 Jul 22 126 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 58 RT signal control: RTS1 output; 12H[7:4] The polarity of any signal on RTS1 can be inverted via RTP1[11H[6]]. RTS1 OUTPUT 3-state Constant LOW CREF (13.5 MHz toggling pulse; see Fig.30) CREF2 (6.75 MHz toggling pulse; see Fig.30) HL; horizontal lock indicator (note 1): HL = 0: unlocked HL = 1: locked VL; vertical and horizontal lock: VL = 0: unlocked VL = 1: locked DL; vertical and horizontal lock and colour detected: DL = 0: unlocked DL = 1: locked Reserved HREF, horizontal reference signal; indicates 720 pixels valid data on the expansion port. The positive slope marks the beginning of a new active line. HREF is also generated during the vertical blanking interval (see Fig.30). HS: programmable width in LLC8 steps via HSB[7:0] 06H[7:0] and HSS[7:0] 07H[7:0] fine position adjustment in LLC2 steps via HDEL[1:0] 11H[5:4] (see Fig.30) HQ; HREF gated with VGATE Reserved V123; vertical sync (see vertical timing diagrams Figs 28 and 29) VGATE; programmable via VSTA[8:0] 17H[0] 15H[7:0], VSTO[8:0] 17H[1] 16H[7:0] and VGPS[17H[2]] Reserved FID; position programmable via VSTA[8:0] 17H[0] 15H[7:0]; see vertical timing diagrams Figs 28 and 29 Note 1. Function of HL is selectable via HLSEL[13H[3]]: a) HLSEL = 0: HL is standard horizontal lock indicator. 1 1 1 1 1 1 0 0 1 1 1 1 0 1 1 0 0 1 0 1 SAF7118 RTSE13 RTSE12 RTSE11 RTSE10 0 0 0 0 0 0 0 0 0 1 0 0 1 1 0 0 1 0 1 0 0 1 1 0 1 0 1 0 1 0 0 1 1 1 0 0 1 1 0 1 0 1 0 1 b) HLSEL = 1: HL is fast horizontal lock indicator (use is not recommended for sources with unstable timebase e.g. VCRs). 2004 Jul 22 127 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.20 SUBADDRESS 13H Table 59 RT/X port output control; 13H[7:0] BIT D7 D6 DESCRIPTION RTCO output enable X port XRH output selection SYMBOL VALUE RTCE XRHS 0 1 0 1 3-state enabled HREF (see Fig.30) HS: FUNCTION SAF7118 programmable width in LLC8 steps via HSB[7:0] 06H[7:0] and HSS[7:0] 07H[7:0] fine position adjustment in LLC2 steps via HDEL[1:0] 11H[5:4] (see Fig.30) D[5:4] X port XRV output selection XRVS[1:0] 00 01 10 11 D3 horizontal lock indicator selection HLSEL OFTS[2:0] 0 1 000 001 V123 (see Figs 28 and 29) ITU 656 related field ID (see Figs 28 and 29) inverted V123 inverted ITU 656 related field ID copy of inverted HLCK status bit (default) fast horizontal lock indicator (for special applications only) ITU 656 ITU 656 like format with modified field blanking according to VGATE position (programmable via VSTA[8:0] 17H[0] 15H[7:0], VSTO[8:0] 17H[1] 16H[7:0] and VGPS[17H[2]]) Y-CB-CR 4 : 2 : 2 8-bit format (no SAV/EAV codes inserted) reserved multiplexed AD2/AD1 or AD4/AD3 bypass (bits D8 to D1) dependent on mode settings (see Section 15.2.3); if two ADCs are selected AD2/AD4 is output at CREF = 1 and AD1/AD3 is output at CREF = 0 multiplexed AD2/AD1 or AD4/AD3 bypass (bits D7 to D0) dependent on mode settings (see Section 15.2.3); if two ADCs are selected AD2/AD4 is output at CREF = 1 and AD1/AD3 is output at CREF = 0 reserved multiplexed ADC MSB/LSB bypass dependent on mode settings; only one ADC should be selected at a time; ADx8 to ADx1 are outputs at CREF = 1 and ADx7 to ADx0 are outputs at CREF = 0 D[2:0] XPD7 to XPD0 (port output format selection); see Section 9.5 010 011 100 101 110 111 2004 Jul 22 128 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.21 SUBADDRESS 14H Table 60 Analog/ADC/auto/compatibility control; 14H[7:0] BIT D7 DESCRIPTION compatibility bit for SAA7199 update time interval for AGC value SYMBOL CM99 VALUE 0 1 UPTCV AOSL[2:0] 0 1 000 001 010 011 100 101 110 111 D3 D2 XTOUT output enable automatic chrominance standard detection control 1 ADC sample clock phase delay XTOUTE AUTO1 0 1 off (default) FUNCTION SAF7118 on (to be set only if SAA7199 is used for re-encoding in conjunction with RTCO active) horizontal update (once per line) vertical update (once per field) AOUT connected to ground AOUT connected to input AD1 AOUT connected to input AD2 AOUT connected to input AD3 AOUT connected to input AD4 reserved reserved AOUT connected to internal test point BPFOUT XTOUT 3-stated XTOUT enabled see Section 15.2.15 D6 23H[7] analog test select and 14H[5:4] D[1:0] APCK[1:0] 00 01 10 11 application dependent 2004 Jul 22 129 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 15.2.22 SUBADDRESS 15H 2004 Jul 22 2004 Jul 22 130 130 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input Table 61 VGATE start; FID polarity change; 17H[0] and 15H[7:0] Start of VGATE pulse (LOW-to-HIGH transition) and polarity change of FID pulse, VGPS = 0; see Figs 28 and 29. FRAME LINE COUNTING 1st 2nd 1st 2nd 1st 2nd 60 Hz 1st 2nd 1st 2nd 1st 2nd 1 314 2 315 312 625 4 267 5 268 265 3 ...260 1 0 0 0 0 0 1 0 1 0... 0 0 0 0 0 0 0 0 0 262 1 0 0 0 0 0 1 1 0 ...310 1 0 0 1 1 0 1 1 1 0... 0 0 0 0 0 0 0 0 0 DECIMAL VALUE 312 MSB 17H[0] VSTA8 50 Hz 1 VSTA7 0 VSTA6 0 CONTROL BITS D7 TO D0 VSTA5 1 VSTA4 1 VSTA3 1 VSTA2 0 VSTA1 0 VSTA0 0 FIELD Product specification SAF7118 SAF7118 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... 15.2.23 SUBADDRESS 16H 2004 Jul 22 2004 Jul 22 131 131 Philips Semiconductors Multistandard video decoder with adaptive comb filter and component video input comb filter and component video input Table 62 VGATE stop; 17H[1] and 16H[7:0] Stop of VGATE pulse (HIGH-to-LOW transition), VGPS = 0; see Figs 28 and 29. FRAME LINE COUNTING 1st 2nd 1st 2nd 1st 2nd 60 Hz 1st 2nd 1st 2nd 1st 2nd 1 314 2 315 312 625 4 267 5 268 265 3 ...260 1 0 0 0 0 0 1 0 1 0... 0 0 0 0 0 0 0 0 0 262 1 0 0 0 0 0 1 1 0 ...310 1 0 0 1 1 0 1 1 1 0... 0 0 0 0 0 0 0 0 0 DECIMAL VALUE 312 MSB 17H[1] VSTO8 50 Hz 1 VSTO7 0 VSTO6 0 CONTROL BITS D7 TO D0 VSTO5 1 VSTO4 1 VSTO3 1 VSTO2 0 VSTO1 0 VSTO0 0 FIELD Product specification SAF7118 SAF7118 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.24 SUBADDRESS 17H Table 63 Miscellaneous/VGATE MSBs; 17H[7:0] BIT D7 D6 DESCRIPTION LLC output enable LLC2 output enable SYMBOL VALUE LLCE LLC2E LATY[2:0] 0 1 0 1 D[5:3] standard detection search loop latency 000 001 010 011 ... 111 D2 D1 D0 alternative VGATE position MSB VGATE stop MSB VGATE start VGPS VSTO8 VSTA8 0 1 enable 3-state enable 3-state reserved one field two fields three fields; recommended setting ... to ... seven fields FUNCTION SAF7118 VGATE position according to Tables 61 and 62 VGATE occurs one line earlier during field 2 see Table 62 see Table 61 15.2.25 SUBADDRESS 18H Table 64 Raw data gain control; RAWG[7:0] 18H[7:0]; see Fig.20 CONTROL BITS D7 TO D0 GAIN RAWG7 255 (double amplitude) 128 (nominal level) 0 (off) 15.2.26 SUBADDRESS 19H Table 65 Raw data offset control; RAWO[7:0] 19H[7:0]; see Fig.20 CONTROL BITS D7 TO D0 OFFSET RAWO7 -128 LSB 0 LSB +128 LSB 0 1 1 RAWO6 0 0 1 RAWO5 0 0 1 RAWO4 0 0 1 RAWO3 0 0 1 RAWO2 0 0 1 RAWO1 0 0 1 RAWO0 0 0 1 0 0 0 RAWG6 1 1 0 RAWG5 1 0 0 RAWG4 1 0 0 RAWG3 1 0 0 RAWG2 1 0 0 RAWG1 1 0 0 RAWG0 1 0 0 2004 Jul 22 132 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.2.27 SUBADDRESS 1EH Table 66 Status byte 1 video decoder; 1EH[6:0]; read only register BIT D6 D5 D4 D3 D2 D[1:0] DESCRIPTION status bit for locked horizontal frequency slow time constant active in WIPA mode gain value for active luminance channel is limited; maximum (top) gain value for active luminance channel is limited; minimum (bottom) white peak loop is activated detected colour standard I2C-BUS CONTROL BIT HLCK SLTCA GLIMT GLIMB WIPA DCSTD[1:0] VALUE 0 1 0 1 0 1 0 1 0 1 00 01 10 11 15.2.28 SUBADDRESS 1FH Table 67 Status byte 2 video decoder; 1FH[7:5] and 1FH[3:0]; read only register BIT D7 D6 D5 D3 D2 D1 D0 DESCRIPTION status bit for interlace detection status bit for horizontal and vertical loop identification bit for detected field frequency Macrovision encoded colour stripe burst type 3 (4 line version) detected Macrovision encoded colour stripe burst detected (any type) copy protected source detected according to Macrovision version up to 7.01 ready for capture (all internal loops locked) I2C-BUS CONTROL BIT INTL HLVLN FIDT TYPE3 COLSTR COPRO RDCAP VALUE 0 1 0 1 0 1 0 1 0 1 0 1 0 1 SAF7118 FUNCTION locked unlocked not active active not active active not active active not active active no colour (black-white) NTSC PAL SECAM FUNCTION non-interlaced interlaced both loops locked unlocked 50 Hz 60 Hz not active active not active active not active active not active active 2004 Jul 22 133 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.3 15.3.1 Programming register RGB/Y-PB-PR component input processing SUBADDRESS 23H SAF7118 Table 68 Analog input control 5 (AICO5); 23H[7:4] and 23H[2:0] BIT DESCRIPTION SYMBOL VALUE AOSL2 ADPE EXCLK 0 1 D5 ADC clock selector 0 1 D4 clamping/reference selection for all ADCs D2 enable external source switch indicator input EXMCLR D1 static gain control channel 2 sign bit D0 static gain control channel 1 sign bit 15.3.2 SUBADDRESS 24H REFA EXMCE 0 1 0 1 GAI48 GAI38 AD port is enabled all ADCs are clocked by the internal generated line-locked clock all ADCs are clocked by the external input clock on CLKEXT clamping is dependent on HLNRS[03H[6]] reference selection (input signal is pulled into ADC range) disabled enabled (any slope on EXMCLR input will reset the internal gain control loop) see Table 70 see Table 69 AD port is set to 3-state FUNCTION see Table 60 D7 analog output select D6 AD port output enable Table 69 Analog input control 6 (AICO6): static gain control channel 3; 23H[0] and 24H[7:0] DECIMAL VALUE 0... ...144 145... ...511 15.3.3 GAIN (dB) -3 0 0 +6 SIGN BIT 23H[0] GAI38 0 0 0 1 GAI37 0 1 1 1 GAI36 0 0 0 1 CONTROL BITS D7 TO D0 GAI35 0 0 0 1 GAI34 0 1 1 1 GAI33 0 0 0 1 GAI32 0 0 0 1 GAI31 0 0 0 1 GAI30 0 0 1 1 SUBADDRESS 25H Table 70 Analog input control 7 (AICO7): static gain control channel 4; 23H[1] and 25H[7:0] DECIMAL VALUE 0... ...144 145... ...511 GAIN (dB) -3 0 0 +6 SIGN BIT 23H[1] GAI48 0 0 0 1 GAI47 0 1 1 1 GAI46 0 0 0 1 CONTROL BITS D7 TO D0 GAI45 0 0 0 1 GAI44 0 1 1 1 GAI43 0 0 0 1 GAI42 0 0 0 1 GAI41 0 0 0 1 GAI40 0 0 1 1 2004 Jul 22 134 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.3.4 SUBADDRESS 29H SAF7118 Table 71 Component delay/fast switch control; 29H[7:0] BIT D7 DESCRIPTION fast switch enable SYMBOL FSWE VALUE 0 1 disabled pixelwise switching between decoded CVBS signal and component input signal is enabled (should only be used for component sources synchronous to CVBS input) FSW = 0: decoded CVBS signal, FSW = 1: component signal FSW = 1: decoded CVBS signal, FSW = 0: component signal for modes 00H to 1FH for modes 20H to 3FH 0 pixel (default) +1 pixel -2 pixel -1 pixel disabled enabled (+1.5 dB at 5 MHz) 0 pixel (default) +4 pixel +8 pixel +12 pixel -16 pixel -12 pixel -8 pixel -4 pixel FUNCTION D6 fast switch input polarity if FSWE = 1 static selection if FSWE = 0 FSWI 0 1 0 1 D[5:4] fast switch input delay adjustment relative to component input signal D3 component luminance peaking FSWDL[1:0] 00 01 10 11 CMFI CPDL[2:0] 0 1 000 001 010 011 100 101 110 111 D[2:0] component input delay adjustment relative to decoded CVBS signal 15.3.5 SUBADDRESS 2AH Table 72 Luminance brightness control component part; 2AH[7:0] CONTROL BITS D7 TO D0 OFFSET CBRI7 255 (bright) 128 (ITU level) 0 (dark) 1 1 0 CBRI6 1 0 0 CBRI5 1 0 0 CBRI4 1 0 0 CBRI3 1 0 0 CBRI2 1 0 0 CBRI1 1 0 0 CBRI0 1 0 0 2004 Jul 22 135 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.3.6 SUBADDRESS 2BH SAF7118 Table 73 Luminance contrast control component part; 2BH[7:0] CONTROL BITS D7 TO D0 GAIN CCON7 1.984 (maximum) 1.0 (ITU level) 0 (luminance off) -1.0 (inverse luminance) -2.0 (inverse luminance) 15.3.7 SUBADDRESS 2CH 0 0 0 1 1 CCON6 1 1 0 1 0 CCON5 1 0 0 0 0 CCON4 1 0 0 0 0 CCON3 1 0 0 0 0 CCON2 1 0 0 0 0 CCON1 1 0 0 0 0 CCON0 1 0 0 0 0 Table 74 Chrominance saturation control component part; 2CH[7:0] CONTROL BITS D7 TO D0 GAIN CSAT7 1.984 (maximum) 1.0 (ITU level) 0 (colour off) -1.0 (inverse chrominance) -2.0 (inverse chrominance) 15.4 Interrupt mask registers 0 0 0 1 1 CSAT6 1 1 0 1 0 CSAT5 1 0 0 0 0 CSAT4 1 0 0 0 0 CSAT3 1 0 0 0 0 CSAT2 1 0 0 0 0 CSAT1 1 0 0 0 0 CSAT0 1 0 0 0 0 See also Section 9.4 15.4.1 SUBADDRESS 2DH Table 75 Interrupt mask 1; 2DH[4:2] and 2DH[1] BIT DESCRIPTION SYMBOL MVPSV MPPV MCCV MERROF VALUE FUNCTION 0 1 D3 interrupt enable `PALplus detected/lost' (corresponding flag: 60H[3]) D2 interrupt enable `closed caption detected/lost' (corresponding flag: 60H[2]) D0 interrupt enable `error output formatter' (corresponding flag: 8FH[2]) 0 1 0 1 0 1 disabled enabled disabled enabled disabled enabled disabled enabled D4 interrupt enable `VPS signal detected/lost' (corresponding flag: 60H[4]) 2004 Jul 22 136 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.4.2 SUBADDRESS 2EH SAF7118 Table 76 Interrupt mask 2; 2EH[6] and 2EH[1:0] BIT DESCRIPTION SYMBOL MHLCK MDCSTD1 MDCSTD0 VALUE FUNCTION 0 1 0 1 D0 interrupt enable `colour standard changed 0' (corresponding flag: 1EH[0]) 0 1 15.4.3 SUBADDRESS 2FH disabled enabled disabled enabled disabled enabled D6 interrupt enable `horizontal PLL locked/unlocked' (corresponding flag: 1EH[6]) D1 interrupt enable `colour standard changed 1' (corresponding flag: 1EH[1]) Table 77 Interrupt mask 3; 2FH[7:5] and 2FH[3:0] BIT DESCRIPTION SYMBOL MINTL MHLVLN MFIDT MTYPE3 MCOLSTR MCOPRO MRDCAP VALUE FUNCTION 0 1 0 1 0 1 D3 interrupt enable `colour stripe type 3 burst detected/lost' (corresponding flag: 1FH[3]) D2 interrupt enable `colour stripe burst (any type) detected/lost' (corresponding flag: 1FH[2]) D1 interrupt enable `copy protected signal found/lost' (corresponding flag: 1FH[1]) D0 interrupt enable `ready for capture/not ready' (corresponding flag: 1FH[0]) 0 1 0 1 0 1 0 1 15.5 Programming register audio clock generation disabled enabled disabled enabled disabled enabled disabled enabled disabled enabled disabled enabled disabled enabled D7 interrupt enable `interlaced/non-interlaced source' (corresponding flag: 1FH[7]) D6 interrupt enable `horizontal and vertical lock reached/lost' (corresponding flag: 1FH[6]) D5 interrupt enable `field frequency has changed' (corresponding flag: 1FH[5]) See equations in Section 8.7 and examples in Tables 22 and 23. 15.5.1 SUBADDRESSES 30H TO 32H Table 78 Audio master clock (AMCLK) cycles per field SUBADDRESS 30H 31H 32H ACPF7 ACPF15 - ACPF6 ACPF14 - ACPF5 ACPF13 - CONTROL BITS D7 TO D0 ACPF4 ACPF12 - ACPF3 ACPF11 - ACPF2 ACPF10 - ACPF1 ACPF9 ACPF17 ACPF0 ACPF8 ACPF16 2004 Jul 22 137 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.5.2 SUBADDRESSES 34H TO 36H SAF7118 Table 79 Audio master clock (AMCLK) nominal increment SUBADDRESS 34H 35H 36H 15.5.3 ACNI7 ACNI15 - ACNI6 ACNI14 - ACNI5 ACNI13 ACNI21 CONTROL BITS D7 TO D0 ACNI4 ACNI12 ACNI20 ACNI3 ACNI11 ACNI19 ACNI2 ACNI10 ACNI18 ACNI1 ACNI9 ACNI17 ACNI0 ACNI8 ACNI16 SUBADDRESS 38H Table 80 Clock ratio audio master clock (AMXCLK) to serial bit clock (ASCLK) SUBADDRESS 38H 15.5.4 - - SDIV5 CONTROL BITS D7 TO D0 SDIV4 SDIV3 SDIV2 SDIV1 SDIV0 SUBADDRESS 39H Table 81 Clock ratio serial bit clock (ASCLK) to channel select clock (ALRCLK) SUBADDRESS 39H 15.5.5 - - LRDIV5 CONTROL BITS D7 TO D0 LRDIV4 LRDIV3 LRDIV2 LRDIV1 LRDIV0 SUBADDRESS 3AH Table 82 Audio clock control; 3AH[3:0] BIT D3 D2 D1 D0 DESCRIPTION audio PLL modes audio master clock vertical reference ALRCLK phase ASCLK phase SYMBOL VALUE APLL AMVR LRPH SCPH 0 1 0 1 0 1 0 1 15.6 15.6.1 Programming register VBI data slicer SUBADDRESS 40H FUNCTION PLL active, AMCLK is field-locked PLL open, AMCLK is free-running vertical reference pulse is taken from internal decoder vertical reference is taken from XRV input (expansion port) ALRCLK edges triggered by falling edges of ASCLK ALRCLK edges triggered by rising edges of ASCLK ASCLK edges triggered by falling edges of AMCLK ASCLK edges triggered by rising edges of AMCLK Table 83 Slicer control 1; 40H[6:4] BIT D6 DESCRIPTION Hamming check SYMBOL VALUE HAM_N 0 1 D5 D4 framing code error amplitude searching FCE HUNT_N 0 1 0 1 FUNCTION Hamming check for 2 bytes after framing code, dependent on data type (default) no Hamming check one framing code error allowed no framing code errors allowed amplitude searching active (default) amplitude searching stopped 2004 Jul 22 138 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.6.2 SUBADDRESSES 41H TO 57H SAF7118 Table 84 Line control register; LCR2 to LCR24 (41H to 57H) See Sections 8.3 and 8.5. D[7:4] (41H TO 57H) NAME DESCRIPTION FRAMING CODE DT[3:0] 62H[3:0] (FIELD 1) WST625 CC625 VPS WSS WST525 CC525 Test line Intercast VITC625 VITC525 Reserved NABTS Japtext JFS teletext EuroWST, CCST European closed caption video programming service wide screen signalling bits US teletext (WST) US closed caption (line 21) video component signal, VBI region raw data VITC/EBU time codes (Europe) VITC/SMPTE time codes (USA) reserved US NABTS MOJI (Japanese) Japanese format switch (L20/22) 27H 001 9951H 1E3C1FH 27H 001 - - programmable programmable programmable - - programmable (A7H) programmable - 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 DT[3:0] 62H[3:0] (FIELD 2) 0000 0001 0010 0011 0100 0101 0110 0111 1000 1001 1010 1011 1100 1101 1110 1111 D[3:0] (41H TO 57H) General text teletext Active video video component signal, active video region (default) 15.6.3 SUBADDRESS 58H Table 85 Programmable framing code; slicer set 58H[7:0] According to Tables 15 and 84. FRAMING CODE FOR PROGRAMMABLE DATA TYPES Default value 15.6.4 SUBADDRESS 59H CONTROL BITS D7 TO D0 FC[7:0] = 40H Table 86 Horizontal offset for slicer; slicer set 59H and 5BH HORIZONTAL OFFSET Recommended value CONTROL BITS 5BH[2:0] HOFF[10:8] = 3H CONTROL BITS 59H[7:0] HOFF[7:0] = 47H 2004 Jul 22 139 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.6.5 SUBADDRESS 5AH SAF7118 Table 87 Vertical offset for slicer; slicer set 5AH and 5BH CONTROL BIT 5BH[4] VERTICAL OFFSET VOFF8 Minimum value 0 Maximum value 312 Value for 50 Hz 625 lines input Value for 60 Hz 525 lines input 15.6.6 SUBADDRESS 5BH 0 1 0 0 VOFF[7:0] 00H 38H 03H 06H CONTROL BITS 5AH[7:0] Table 88 Field offset, and MSBs for horizontal and vertical offsets; slicer set 5BH[7:6] See Sections 15.6.4 and 15.6.5 for HOFF[10:8] 5BH[2:0] and VOFF8[5BH[4]]. BIT D7 DESCRIPTION field offset SYMBOL FOFF VALUE 0 1 D6 recode RECODE 0 1 15.6.7 SUBADDRESS 5DH FUNCTION no modification of internal field indicator (default for 50 Hz 625 lines input sources) invert field indicator (default for 60 Hz 525 lines input sources) leave data unchanged (default) convert 00H and FFH data bytes into 03H and FCH Table 89 Header and data identification (DID; ITU 656) code control; slicer set 5DH[7:0] BIT D7 DESCRIPTION field ID and V-blank selection for text output (F and V reference selection) SYMBOL FVREF VALUE 0 1 DID[5:0] FUNCTION F and V output of slicer is LCR table dependent F and V output is taken from decoder real-time signals EVEN_ITU and VBLNK_ITU D[5:0] default; DID[5:0] = 00H special cases of DID programming 15.6.8 SUBADDRESS 5EH 00 0000 ANC header framing; see Fig.37 and Table 21 11 1110 DID[5:0] = 3EH SAV/EAV framing, with FVREF = 1 11 1111 DID[5:0] = 3FH SAV/EAV framing, with FVREF = 0 Table 90 Sliced data identification (SDID) code; slicer set 5EH[5:0] BIT DESCRIPTION SYMBOL SDID[5:0] VALUE 00H default FUNCTION D[5:0] SDID codes 2004 Jul 22 140 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.6.9 SUBADDRESS 60H SAF7118 Table 91 Slicer status byte 0; 60H[6:2]; read only register BIT D6 D5 D4 D3 D2 DESCRIPTION framing code valid framing code valid VPS valid PALplus valid closed caption valid SYMBOL FC8V FC7V VPSV PPV CCV VALUE 0 1 0 1 0 1 0 1 0 1 15.6.10 SUBADDRESSES 61H AND 62H Table 92 Slicer status byte 1; 61H[5:0] and slicer status byte 2; 62H[7:0]; read only registers SUBADDRESS 61H 62H BIT D5 D[4:0] D[7:4] D[3:0] 15.7 15.7.1 SYMBOL F21_N LN[8:4] LN[3:0] DT[3:0] data type; according to Table 15 line number DESCRIPTION field ID as seen by the VBI slicer; for field 1: D5 = 0 FUNCTION no framing code (0 error) in the last frame detected framing code with 0 error detected no framing code (1 error) in the last frame detected framing code with 1 error detected no VPS in the last frame VPS detected no PALplus in the last frame PALplus detected no closed caption in the last frame closed caption detected Programming register interfaces and scaler part SUBADDRESS 80H Table 93 Global control 1; global set 80H[6:4]; note 1 SWRST moved to subaddress 88H[5]. CONTROL BITS D6 TO D4 TASK ENABLE CONTROL SMOD Task of register set A is disabled Task of register set A is enabled Task of register set B is disabled Task of register set B is enabled The scaler window defines the F and V timing of the scaler output VBI data slicer defines the F and V timing of the scaler output Note 1. X = don't care. X X X X 0 1 TEB X X 0 1 X X TEA 0 1 X X X X 2004 Jul 22 141 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 94 Global control 1; global set 80H[3:0]; note 1 SAF7118 CONTROL BITS D3 TO D0 I PORT AND SCALER BACK-END CLOCK SELECTION ICKS3 ICLK output and back-end clock is line-locked clock LLC from decoder ICLK output and back-end clock is XCLK from X port ICLK output is LLC and back-end clock is LLC2 clock Back-end clock is the ICLK input IDQ pin carries the data qualifier IDQ pin carries a gated back-end clock (DQ AND CLK) IDQ generation only for valid data IDQ qualifies valid data inside the scaling region and all data outside the scaling region Notes 1. X = don't care. 2. Although the ICLKO I/O is independent of ICKS2 and ICKS3, this selection can only be used if ICKS2 = 1. 15.7.2 SUBADDRESSES 83H TO 87H X X X X X X 0 1 ICKS2 X X X(2) X 0 1 X X ICKS1 0 0 1 1 X X X X ICKS0 0 1 0 1 X X X X Table 95 X port I/O enable and output clock phase control; global set 83H[5:4] CONTROL BITS D5 AND D4 OUTPUT CLOCK PHASE CONTROL XPCK1 XCLK default output phase, recommended value XCLK output inverted XCLK phase shifted by approximately 3 ns XCLK output inverted and shifted by approximately 3 ns Table 96 X port I/O enable and output clock phase control; global set 83H[2:0]; note 1 CONTROL BITS D2 TO D0 X PORT I/O ENABLE XRQT X port output is disabled by software X port output is enabled by software X port output is enabled by pin XTRI at logic 0 X port output is enabled by pin XTRI at logic 1 XRDY output signal is A/B task flag from event handler (A = 1) XRDY output signal is ready signal from scaler path (XRDY = 1 means the SAF7118 is ready to receive data) Note 1. X = don't care. X X X X 0 1 XPE1 0 0 1 1 X X XPE0 0 1 0 1 X X 0 0 1 1 XPCK0 0 1 0 1 2004 Jul 22 142 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 97 I port signal definitions; global set 84H[7:6] and 86H[5] SAF7118 CONTROL BITS I PORT SIGNAL DEFINITIONS 86H[5] IDG02 IGP0 is output field ID, as defined by OFIDC[90H[6]] IGP0 is A/B task flag, as defined by CONLH[90H[7]] IGP0 is sliced data flag, framing the sliced VBI data at the I port IGP0 is set to logic 0 (default polarity) IGP0 is the output FIFO almost filled flag IGP0 is the output FIFO overflow flag IGP0 is the output FIFO almost full flag, level to be programmed in subaddress 86H IGP0 is the output FIFO almost empty flag, level to be programmed in subaddress 86H Table 98 I port signal definitions; global set 84H[5:4] and 86H[4] CONTROL BITS I PORT SIGNAL DEFINITIONS 86H[4] IDG12 IGP1 is output field ID, as defined by OFIDC[90H[6]] IGP1 is A/B task flag, as defined by CONLH[90H[7]] IGP1 is sliced data flag, framing the sliced VBI data at the I port IGP1 is set to logic 0 (default polarity) IGP1 is the output FIFO almost filled flag IGP1 is the output FIFO overflow flag IGP1 is the output FIFO almost full flag, level to be programmed in subaddress 86H IGP1 is the output FIFO almost empty flag, level to be programmed in subaddress 86H Table 99 I port output signal definitions; global set 84H[3:0]; note 1 CONTROL BITS D3 TO D0 I PORT OUTPUT SIGNAL DEFINITIONS IDV1 IGPH is a H gate signal, framing the scaler output IGPH is an extended H gate (framing H gate during scaler output and scaler input H reference outside the scaler window) IGPH is a horizontal trigger pulse, on active going edge of H gate IGPH is a horizontal trigger pulse, on active going edge of extended H gate IGPV is a V gate signal, framing scaled output lines IGPV is the V reference signal from scaler input IGPV is a vertical trigger pulse, derived from V gate IGPV is a vertical trigger pulse derived from input V reference Note 1. X = don't care. X X X X 0 0 1 1 IDV0 X X X X 0 1 0 1 IDH1 0 0 1 1 X X X X IDH0 0 1 0 1 X X X X 0 0 0 0 1 1 1 1 84H[5:4] IDG11 0 0 1 1 0 0 1 1 IDG10 0 1 0 1 0 1 0 1 0 0 0 0 1 1 1 1 84H[7:6] IDG01 0 0 1 1 0 0 1 1 IDG00 0 1 0 1 0 1 0 1 2004 Jul 22 143 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 100 X port signal definitions text slicer; global set 85H[7:5]; note 1 SAF7118 CONTROL BITS D7 TO D5 X PORT SIGNAL DEFINITIONS TEXT SLICER ISWP1 Video data limited to range 1 to 254 Video data limited to range 8 to 247 Dword byte swap, influences serial output timing D0 D1 D2 D3 FF 00 00 SAV CB0 Y0 CR0 Y1 D1 D0 D3 D2 00 FF SAV 00 Y0 CB0 Y1 CR0 D2 D3 D0 D1 00 SAV FF 00 CR0 Y1 CB0 Y0 D3 D2 D1 D0 SAV 00 00 FF Y1 CR0 Y0 CB0 Note 1. X = don't care. Table 101 I port reference signal polarities; global set 85H[4:0]; note 1 CONTROL BITS D4 TO D0 I PORT REFERENCE SIGNAL POLARITIES IG0P IDQ at default polarity (1 = active) IDQ is inverted IGPH at default polarity (1 = active) IGPH is inverted IGPV at default polarity (1 = active) IGPV is inverted IGP1 at default polarity IGP1 is inverted IGP0 at default polarity IGP0 is inverted Note 1. X = don't care. X X X X X X X X 0 1 IG1P X X X X X X 0 1 X X IRVP X X X X 0 1 X X X X IRHP X X 0 1 X X X X X X IDQP 0 1 X X X X X X X X X X 0 0 1 1 ISWP0 X X 0 1 0 1 ILLV 0 1 X X X X 2004 Jul 22 144 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 102 I port FIFO flag control and arbitration; global set 86H[7:4]; note 1 SAF7118 CONTROL BITS D7 TO D4 FUNCTION VITX1 See subaddress 84H: IDG11 and IDG10 See subaddress 84H: IDG01 and IDG00 I port signal definitions I port data output inhibited Only video data is transferred Only text data is transferred (no EAV, SAV will occur) Text and video data is transferred, text has priority Note 1. X = don't care. Table 103 I port FIFO flag control and arbitration; global set 86H[3:0]; note 1 CONTROL BITS D3 TO D0 I PORT FIFO FLAG CONTROL AND ARBITRATION FFL1 FAE FIFO flag almost empty level <16 Dwords <8 Dwords <4 Dwords 0 Dwords FAF FIFO flag almost full level 16 Dwords 24 Dwords 28 Dwords 32 Dwords Note 1. X = don't care. 0 0 1 1 0 1 0 1 X X X X X X X X X X X X X X X X 0 0 1 1 0 1 0 1 FFL0 FEL1 FEL0 0 0 1 1 0 1 0 1 X X X X X X X X X X X X VITX0 X X X X IDG02 X X 0 1 IDG12 0 1 X X 2004 Jul 22 145 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 104 I port I/O enable, output clock and gated clock phase control; global set 87H[7:4]; note 1 SAF7118 CONTROL BITS D7 TO D4 OUTPUT CLOCK AND GATED CLOCK PHASE CONTROL ICLK default output phase ICLK phase shifted by 12 clock cycle recommended for ICKS1 = 1 and ICKS0 = 0 (subaddress 80H) ICLK phase shifted by approximately 3 ns ICLK phase shifted by 2 clock cycle + approximately 3 ns alternatively to setting `01' IDQ = gated clock default output phase IDQ = gated clock phase shifted by for gated clock output 1 2 1 IPCK3(2) X X X X 0 0 1 1 IPCK2(2) X X X X 0 1 0 1 IPCK1 0 0 1 1 X X X X IPCK0 0 1 0 1 X X X X clock cycle recommended IDQ = gated clock phase shifted by approximately 3 ns IDQ = gated clock phase shifted by 12 clock cycle + approximately 3 ns alternatively to setting `01' Notes 1. X = don't care. 2. IPCK3 and IPCK2 only affects the gated clock (subaddress 80H, bit ICKS2 = 1). Table 105 I port I/O enable, output clock and gated clock phase control; global set 87H[1:0] CONTROL BITS D1 AND D0 I PORT I/O ENABLE IPE1 I port output is disabled by software I port output is enabled by software I port output is enabled by pin ITRI at logic 0 I port output is enabled by pin ITRI at logic 1 0 0 1 1 IPE0 0 1 0 1 2004 Jul 22 146 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.7.3 SUBADDRESS 88H SAF7118 Table 106 ADC port control; global set 88H[7:4]; note 1 CONTROL BITS D7 TO D4 ADC PORT OUTPUT CONTROL/START-UP CONTROL DOSL1 DPROG = 0 after reset DPROG = 1 can be used to assign that the device has been programmed; this bit can be monitored in the scalers status byte, bit PRDON; if DPROG was set to logic 1 and PRDON status bit shows a logic 0 a power-up or start-up fail has occurred Scaler path is reset to its idle state, software reset Scaler is switched back to operation Digitized ADC1 signal is fed to port ADP[8:0] Digitized ADC2 signal is fed to port ADP[8:0] Digitized ADC3 signal is fed to port ADP[8:0] Digitized ADC4 signal is fed to port ADP[8:0] Notes 1. X = don't care. 2. Bit SWRST is now located here. Table 107 Power save control; global set 88H[3] and 88H[1:0]; note 1 CONTROL BITS D3, D1 AND D0 POWER SAVE CONTROL SLM3 Decoder and VBI slicer are in operational mode Decoder and VBI slicer are in power-down mode; scaler only operates, if scaler input and ICLK source is the X port (refer to subaddresses 80H and 91H/C1H) Scaler is in operational mode Scaler is in power-down mode; scaler in power-down stops I port output Audio clock generation active Audio clock generation in power-down and output disabled Note 1. X = don't care. X X X X 0 1 SLM1 X X 0 1 X X SLM0 0 1 X X X X X X DOSL0 X X SWRST(2) X X DPROG 0 1 X X 0 0 1 1 X X 0 1 0 1 0 1 X X X X X X X X X X 2004 Jul 22 147 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.7.4 SUBADDRESS 8FH SAF7118 Table 108 Status information scaler part; 8FH[7:0]; read only register BIT D7 D6 D5 D4 D3 D2 I2C-BUS STATUS BIT XTRI ITRI FFIL FFOV PRDON ERROF FUNCTION(1) status on input pin XTRI, if not used for 3-state control, usable as hardware flag for software use status on input pin ITRI, if not used for 3-state control, usable as hardware flag for software use status of the internal `FIFO almost filled' flag status of the internal `FIFO overflow' flag copy of bit DPROG, can be used to detect power-up and start-up fails error flag of scalers output formatter, normally set, if the output processing needs to be interrupted, due to input/output data rate conflicts, e.g. if output data rate is much too low and all internal FIFO capacity used status of the field sequence ID at the scalers input status of the field sequence ID at the scalers output, scaler processing dependent D1 D0 Note FIDSCI FIDSCO 1. Status information is unsynchronized and shows the actual status at the time of I2C-bus read. 15.7.5 SUBADDRESSES 90H AND C0H Table 109 Task handling control; register set A [90H[7:6]] and B [C0H[7:6]]; note 1 CONTROL BITS D7 AND D6 EVENT HANDLER CONTROL CONLH Output field ID is field ID from scaler input Output field ID is task status flag, which changes every time a selected task is activated (not synchronized to input field ID) Scaler SAV/EAV byte bit D7 and task flag = 1, default Scaler SAV/EAV byte bit D7 and task flag = 0 Note 1. X = don't care. Table 110 Task handling control; register set A [90H[5:3]] and B [C0H[5:3]] CONTROL BITS D5 TO D3 EVENT HANDLER CONTROL FSKP2 Active task is carried out directly 1 field is skipped before active task is carried out ... fields are skipped before active task is carried out 6 fields are skipped before active task is carried out 7 fields are skipped before active task is carried out 0 0 ... 1 1 FSKP1 0 0 ... 1 1 FSKP0 0 1 ... 0 1 X X 0 1 OFIDC 0 1 X X 2004 Jul 22 148 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 111 Task handling control; register set A [90H[2:0]] and B [C0H[2:0]]; note 1 SAF7118 CONTROL BITS D2 TO D0 EVENT HANDLER CONTROL RPTSK Event handler triggers immediately after finishing a task Event handler triggers with next V-sync Event handler triggers with field ID = 0 Event handler triggers with field ID = 1 If active task is finished, handling is taken over by the next task Active task is repeated once, before handling is taken over by the next task Note 1. X = don't care. 15.7.6 SUBADDRESSES 91H TO 93H X X X X 0 1 STRC1 0 0 1 1 X X STRC0 0 1 0 1 X X Table 112 X port formats and configuration; register set A [91H[7:3]] and B [C1H[7:3]]; note 1 SCALER INPUT FORMAT AND CONFIGURATION SOURCE SELECTION Only if XRQT[83H[2]] = 1: scaler input source reacts on SAF7118 request Scaler input source is a continuous data stream, which cannot be interrupted (must be logic 1, if SAF7118 decoder part is source of scaler or XRQT[83H[2]] = 0) Scaler input source is data from decoder, data type is provided according to Table 15 Scaler input source is Y-CB-CR data from X port Scaler input source is raw digital CVBS from selected analog channel, for backward compatibility only, further use is not recommended Scaler input source is raw digital CVBS (or 16-bit Y + CB-CR, if no 16-bit outputs are active) from X port SAV/EAV code bits D6 and D5 (F and V) may change between SAV and EAV SAV/EAV code bits D6 and D5 (F and V) are synchronized to scalers output line start SAV/EAV code bit D5 (V) and V gate on pin IGPV as generated by the internal processing; see Fig.43 SAV/EAV code bit D5 (V) and V gate are inverted Note 1. X = don't care. CONTROL BITS D7 TO D3 CONLV X X HLDFV X X SCSRC1 SCSRC0 X X X X SCRQE 0 1 X X X X X X 0 0 1 0 1 0 X X X X X X 0 1 X 0 1 X X 1 X X X X 1 X X X X X X X X X 2004 Jul 22 149 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 113 X port formats and configuration; register set A [91H[2:0]] and B [C1H[2:0]]; note 1 SCALER INPUT FORMAT AND CONFIGURATION FORMAT CONTROL Input is Y-CB-CR 4 : 2 : 2 like sampling scheme Input is Y-CB-CR 4 : 1 : 1 like sampling scheme Chroma is provided every line, default Chroma is provided every 2nd line Chroma is provided every 3rd line Chroma is provided every 4th line Notes 1. X = don't care. SAF7118 CONTROL BITS D2 TO D0 FSC2(2) X X 0 0 1 1 FSC1(2) X X 0 1 0 1 FSC0 0 1 X X X X 2. FSC2 and FSC1 only to be used, if X port input source does not provide chroma information for every input line. X port input stream must contain dummy chroma bytes. Table 114 X port input reference signal definitions; register set A [92H[7:4]] and B [C2H[7:4]]; note 1 CONTROL BITS D7 TO D4 X PORT INPUT REFERENCE SIGNAL DEFINITIONS XFDV Rising edge of XRV input and decoder V123 is vertical reference Falling edge of XRV input and decoder V123 is vertical reference XRV is a V-sync or V gate signal XRV is a frame sync, V pulses are generated internally on both edges of FS input X port field ID is state of XRH at reference edge on XRV (defined by XFDV) Field ID (decoder and X port field ID) is inverted Reference edge for field detection is falling edge of XRV Reference edge for field detection is rising edge of XRV Note 1. X = don't care. X X X X X X 0 1 XFDH X X X X 0 1 X X XDV1 X X 0 1 X X X X XDV0 0 1 X X X X X X 2004 Jul 22 150 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 115 X port input reference signal definitions; register set A [92H[3:0]] and B [C2H[3:0]]; note 1 SAF7118 CONTROL BITS D3 TO D0 X PORT INPUT REFERENCE SIGNAL DEFINITIONS XCODE XCLK input clock and XDQ input qualifier are needed Data rate is defined by XCLK only, no XDQ signal used Data are qualified at XDQ input at logic 1 Data are qualified at XDQ input at logic 0 Rising edge of XRH input is horizontal reference Falling edge of XRH input is horizontal reference Reference signals are taken from XRH and XRV Reference signals are decoded from EAV and SAV Note 1. X = don't care. Table 116 I port output format and configuration; register set A [93H[7:5]] and B [C3H[7:5]]; note 1 CONTROL BITS D7 TO D5 I PORT OUTPUT FORMATS AND CONFIGURATION ICODE All lines will be output Skip the number of leading Y only lines, as defined by FOI1 and FOI0 Dwords are transferred byte wise, see subaddress 85H bits ISWP1 and ISWP0 Dwords are transferred 16-bit word wise via IPD and HPD, see subaddress 85H bits ISWP1 and ISWP0 No ITU 656 like SAV/EAV codes are available ITU 656 like SAV/EAV codes are inserted in the output data stream, framed by a qualifier Note 1. X = don't care. X X X X 0 1 I8_16 X X 0 1 X X FYSK 0 1 X X X X X X X X X X 0 1 XDH X X X X 0 1 X X XDQ X X 0 1 X X X X XCKS 0 1 X X X X X X 2004 Jul 22 151 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 117 I port output format and configuration; register set A [93H[4:0]] and B [C3H[4:0]]; note 1 SAF7118 CONTROL BITS D4 TO D0 I PORT OUTPUT FORMATS AND CONFIGURATION FOI1 4 : 2 : 2 Dword formatting 4 : 1 : 1 Dword formatting 4 : 2 : 0, only every 2nd line Y + CB-CR output, in between Y only output 4 : 1 : 0, only every 4th line Y + CB-CR output, in between Y only output Y only Not defined Not defined Not defined No leading Y only line, before 1st Y + CB-CR line is output 1 leading Y only line, before 1st Y + CB-CR line is output 2 leading Y only lines, before 1st Y + CB-CR line is output 3 leading Y only lines, before 1st Y + CB-CR line is output Note 1. X = don't care. 15.7.7 SUBADDRESSES 94H TO 9BH X X X X X X X X 0 0 1 1 FOI0 X X X X X X X X 0 1 0 1 FSI2 0 0 0 0 1 1 1 1 X X X X FSI1 0 0 1 1 0 0 1 1 X X X X FSI0 0 1 0 1 0 1 0 1 X X X X Table 118 Horizontal input window start; register set A [94H[7:0]; 95H[3:0]] and B [C4H[7:0]; C5H[3:0]] HORIZONTAL INPUT ACQUISITION WINDOW DEFINITION OFFSET IN X (HORIZONTAL) DIRECTION(1) A minimum of `2' should be kept, due to a line counting mismatch Odd offsets are changing the CB-CR sequence in the output stream to CR-CB sequence Maximum possible pixel offset = 4095 Note 1. Reference for counting are luminance samples. CONTROL BITS A [95H[3:0]] B [C5H[3:0]] A [94H[7:0]] B [C4H[7:0]] XO11 XO10 XO9 XO8 XO7 XO6 XO5 XO4 XO3 XO2 XO1 XO0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 2004 Jul 22 152 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 Table 119 Horizontal input window length; register set A [96H[7:0]; 97H[3:0]] and B [C6H[7:0]; C7H[3:0]] HORIZONTAL INPUT ACQUISITION WINDOW DEFINITION INPUT WINDOW LENGTH IN X (HORIZONTAL) DIRECTION(1) No output Odd lengths are allowed, but will be rounded up to even lengths Maximum possible number of input pixels = 4095 Note 1. Reference for counting are luminance samples. Table 120 Vertical input window start; register set A [98H[7:0]; 99H[3:0]] and B [C8H[7:0]; C9H[3:0]] CONTROL BITS VERTICAL INPUT ACQUISITION WINDOW DEFINITION OFFSET IN Y (VERTICAL) DIRECTION(1) Line offset = 0 Line offset = 1 Maximum line offset = 4095 Note 1. For trigger condition: STRC[1:0] 90H[1:0] = 00; YO + YS > (number of input lines per field - 2), will result in field dropping. Other trigger conditions: YO > (number of input lines per field - 2), will result in field dropping. Table 121 Vertical input window length; register set A [9AH[7:0]; 9BH[3:0]] and B [CAH[7:0]; CBH[3:0]] VERTICAL INPUT ACQUISITION WINDOW DEFINITION INPUT WINDOW LENGTH IN Y (VERTICAL) DIRECTION(1) No input lines 1 input line Maximum possible number of input lines = 4095 Note 1. For trigger condition: STRC[1:0] 90H[1:0] = 00; YO + YS > (number of input lines per field - 2), will result in field dropping. Other trigger conditions: YS > (number of input lines per field - 2), will result in field dropping. CONTROL BITS A [9BH[3:0]] B [CBH[3:0]] YS11 YS10 0 0 1 0 0 1 YS9 0 0 1 A [9AH[7:0]] B [CAH[7:0]] YS8 YS7 YS6 YS5 YS4 YS3 YS2 YS1 YS0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 1 1 0 0 1 A [99H[3:0]] B [C9H[3:0]] A [98H[7:0]] B [C8H[7:0]] CONTROL BITS A [97H[3:0]] B [C7H[3:0]] A [96H[7:0]] B [C6H[7:0]] XS11 XS10 XS9 XS8 XS7 XS6 XS5 XS4 XS3 XS2 XS1 XS0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 1 1 YO11 YO10 YO9 YO8 YO7 YO6 YO5 YO4 YO3 YO2 YO1 YO0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 1 1 2004 Jul 22 153 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.7.8 SUBADDRESSES 9CH TO 9FH SAF7118 Table 122 Horizontal output window length; register set A [9CH[7:0]; 9DH[3:0]] and B [CCH[7:0]; CDH[3:0]] HORIZONTAL OUTPUT ACQUISITION WINDOW DEFINITION NUMBER OF DESIRED OUTPUT PIXELS IN X (HORIZONTAL) DIRECTION(1) No output Odd lengths are allowed, but will be filled up to even lengths Maximum possible number of input pixels = 4095; note 2 Notes 1. Reference for counting are luminance samples. 2. If the desired output length is greater than the number of scaled output pixels, the last scaled pixel is repeated. Table 123 Vertical output window length; register set A [9EH[7:0]; 9FH[3:0]] and B [CEH[7:0]; CFH[3:0]] VERTICAL OUTPUT ACQUISITION WINDOW DEFINITION NUMBER OF DESIRED OUTPUT LINES IN Y (VERTICAL) DIRECTION No output 1 pixel Maximum possible number of output lines = 4095; note 1 Note 1. If the desired output length is greater than the number of scaled output lines, the processing is cut. 15.7.9 SUBADDRESSES A0H TO A2H CONTROL BITS A [9FH[3:0]] B [CFH[3:0]] A [9EH[7:0]] B [CEH[7:0]] CONTROL BITS A [9DH[3:0]] B [CDH[3:0]] A [9CH[7:0]] B [CCH[7:0]] XD11 XD10 XD9 XD8 XD7 XD6 XD5 XD4 XD3 XD2 XD1 XD0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 1 1 YD11 YD10 YD9 YD8 YD7 YD6 YD5 YD4 YD3 YD2 YD1 YD0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 1 1 Table 124 Horizontal prescaling; register set A [A0H[5:0]] and B [D0H[5:0]] CONTROL BITS D5 TO D0 HORIZONTAL INTEGER PRESCALING RATIO (XPSC) XPSC5 XPSC4 XPSC3 XPSC2 XPSC1 XPSC0 Not allowed Downscale = 1 Downscale = 12 ... Downscale = 1 63 0 0 0 ... 1 0 0 0 ... 1 0 0 0 ... 1 0 0 0 ... 1 0 0 1 ... 1 0 1 0 ... 1 2004 Jul 22 154 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 125 Accumulation length; register set A [A1H[5:0]] and B [D1H[5:0]] HORIZONTAL PRESCALER ACCUMULATION SEQUENCE LENGTH (XACL) Accumulation length = 1 Accumulation length = 2 ... Accumulation length = 64 SAF7118 CONTROL BITS D5 TO D0 XACL5 XACL4 XACL3 XACL2 XACL1 XACL0 0 0 ... 1 0 0 ... 1 0 0 ... 1 0 0 ... 1 0 0 ... 1 0 1 ... 1 Table 126 Prescaler DC gain and FIR prefilter control; register set A [A2H[7:4]] and B [D2H[7:4]]; note 1 CONTROL BITS D7 TO D4 FIR PREFILTER CONTROL PFUV1 PFUV0 Luminance FIR filter bypassed H_y(z) = H_y(z) = H_y(z) = 1 4 1 8 1 8 1 PFY1 0 0 1 1 X X X X PFY0 0 1 0 1 X X X X X X X X 0 0 1 1 X X X X 0 1 0 1 (1 2 1) (-1 1 1.75 4.5 1.75 1 -1) (1 2 2 2 1) (1 2 1) Chrominance FIR filter bypassed H_uv(z) = 4 H_uv(z) = 132 (3 8 10 8 3) H_uv(z) = 18 (1 2 2 2 1) Note 1. X = don't care. Table 127 Prescaler DC gain and FIR prefilter control; register set A [A2H[3:0]] and B [D2H[3:0]]; note 1 CONTROL BITS D3 TO D0 PRESCALER DC GAIN XC2_1 Prescaler output is renormalized by gain factor = 1 Prescaler output is renormalized by gain factor = Prescaler output is renormalized by gain factor = Prescaler output is renormalized by gain factor = Prescaler output is renormalized by gain factor = Prescaler output is renormalized by gain factor = 1 1 1 1 1 2 XDCG2 0 0 0 0 1 1 1 1 X X XDCG1 0 0 1 1 0 0 1 1 X X XDCG0 0 1 0 1 0 1 0 1 X X X X X X X X X X 0 1 Prescaler output is renormalized by gain factor = 14 8 16 32 Prescaler output is renormalized by gain factor = 164 128 Weighting of all accumulated samples is factor `1'; e.g. XACL = 4 sequence 1 + 1 + 1 + 1 + 1 Weighting of samples inside sequence is factor `2'; e.g. XACL = 4 sequence 1 + 2 + 2 + 2 + 1 Note 1. X = don't care. 2004 Jul 22 155 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 15.7.10 SUBADDRESSES A4H TO A6H Table 128 Luminance brightness control; register set A [A4H[7:0]] and B [D4H[7:0]] LUMINANCE BRIGHTNESS CONTROL Value = 0 Nominal value = 128 Value = 255 CONTROL BITS D7 TO D0 BRIG7 0 1 1 BRIG6 0 0 1 BRIG5 0 0 1 BRIG4 0 0 1 BRIG3 0 0 1 BRIG2 0 0 1 SAF7118 BRIG1 0 0 1 BRIG0 0 0 1 Table 129 Luminance contrast control; register set A [A5H[7:0]] and B [D5H[7:0]] LUMINANCE CONTRAST CONTROL Gain = 0 Gain = Gain = 1 64 CONTROL BITS D7 TO D0 CONT7 0 0 0 0 CONT6 0 0 1 1 CONT5 0 0 0 1 CONT4 0 0 0 1 CONT3 0 0 0 1 CONT2 0 0 0 1 CONT1 0 0 0 1 CONT0 0 1 0 1 Nominal gain = 64 127 64 Table 130 Chrominance saturation control; register set A [A6H[7:0]] and B [D6H[7:0]] CHROMINANCE SATURATION CONTROL Gain = 0 Gain = 164 Nominal gain = 64 Gain = 127 64 CONTROL BITS D7 TO D0 SATN7 0 0 0 0 SATN6 0 0 1 1 SATN5 0 0 0 1 SATN4 0 0 0 1 SATN3 0 0 0 1 SATN2 0 0 0 1 SATN1 0 0 0 1 SATN0 0 1 0 1 15.7.11 SUBADDRESSES A8H TO AEH Table 131 Horizontal luminance scaling increment; register set A [A8H[7:0]; A9H[7:0]] and B [D8H[7:0]; D9H[7:0]] CONTROL BITS HORIZONTAL LUMINANCE SCALING INCREMENT 1024 (theoretical) zoom 1 1024 294, lower limit defined A [A9H[7:4]] B [D9H[7:4]] XSCY[15:12](1) A [A9H[3:0]] B [D9H[3:0]] XSCY[11:8] 0000 0001 0011 0100 0100 1111 A [A8H[7:4]] B [D8H[7:4]] XSCY[7:4] 0000 0010 1111 0000 0000 1111 A [A8H[3:0]] B [D8H[3:0]] XSCY[3:0] 0000 0110 1111 0000 0001 1111 Scale = 0000 by 0000 0000 0000 0000 0001 Scale = data path structure Scale = 10241023 zoom Scale = 1, equals 1024 Scale = Scale = Note 1024 1025 1024 8191 downscale downscale 1. Bits XSCY[15:13] are reserved and are set to logic 0. 2004 Jul 22 156 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 132 Horizontal luminance phase offset; register set A [AAH[7:0]] and B [DAH[7:0]] HORIZONTAL LUMINANCE PHASE OFFSET Offset = 0 Offset = 132 pixel Offset = 3232 = 1 pixel Offset = 255 32 SAF7118 CONTROL BITS D7 TO D0 XPHY7 0 0 0 1 XPHY6 0 0 0 1 XPHY5 0 0 1 1 XPHY4 0 0 0 1 XPHY3 0 0 0 1 XPHY2 0 0 0 1 XPHY1 0 0 0 1 XPHY0 0 1 0 1 pixel Table 133 Horizontal chrominance scaling increment; register set A [ACH[7:0]; ADH[7:0]] and B [DCH[7:0]; DDH[7:0]] CONTROL BITS HORIZONTAL CHROMINANCE SCALING INCREMENT A [ADH[7:4]] B [DDH[7:4]] XSCC[15:12](1) This value must be set to the luminance value 12XSCY[15:0] 0000 0000 0001 Note 1. Bits XSCC[15:13] are reserved and are set to logic 0. Table 134 Horizontal chrominance phase offset; register set A [AEH[7:0]] and B [DEH[7:0]] HORIZONTAL CHROMINANCE PHASE OFFSET This value must be set to 1 XPHY[7:0] 2 A [ADH[3:0]] B [DDH[3:0]] XSCC[11:8] 0000 0000 1111 A [ACH[7:4]] B [DCH[7:4]] XSCC[7:4] 0000 0000 1111 A [ACH[3:0]] B [DCH[3:0]] XSCC[3:0] 0000 0001 1111 CONTROL BITS D7 TO D0 XPHC7 XPHC6 XPHC5 XPHC4 XPHC3 XPHC2 XPHC1 XPHC0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1 0 1 1 15.7.12 SUBADDRESSES B0H TO BFH Table 135 Vertical luminance scaling increment; register set A [B0H[7:0]; B1H[7:0]] and B [E0H[7:0]; E1H[7:0]] CONTROL BITS VERTICAL LUMINANCE SCALING INCREMENT 1024 (theoretical) 1 1024 1023 zoom A [B1H[7:4]] B [E1H[7:4]] YSCY[15:12] A [B1H[3:0]] B [E1H[3:0]] YSCY[11:8] 0000 0011 0100 0100 1111 A [B0H[7:4]] B [E0H[7:4]] YSCY[7:4] 0000 1111 0000 0000 1111 A [B0H[3:0]] B [E0H[3:0]] YSCY[3:0] 0001 1111 0000 0001 1111 Scale = Scale = Scale = Scale = zoom 0000 0000 0000 0000 1111 Scale = 1, equals 1024 1024 1025 downscale 1 63.999 downscale 2004 Jul 22 157 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 Table 136 Vertical chrominance scaling increment; register set A [B2H[7:0]; B3H[7:0]] and B [E2H[7:0]; E3H[7:0]] CONTROL BITS VERTICAL CHROMINANCE SCALING INCREMENT A [B3H[7:4]] B [E3H[7:4]] YSCC[15:12] This value must be set to the luminance value YSCY[15:0] 0000 1111 A [B3H[3:0]] B [E3H[3:0]] YSCC[11:8] 0000 1111 A [B2H[7:4]] B [E2H[7:4]] YSCC[7:4] 0000 1111 A [B2H[3:0]] B [E2H[3:0]] YSCC[3:0] 0001 1111 Table 137 Vertical scaling mode control; register set A [B4H[4 and 0]] and B [E4H[4 and 0]]; note 1 CONTROL BITS D4 AND D0 VERTICAL SCALING MODE CONTROL YMIR Vertical scaling performs linear interpolation between lines Vertical scaling performs higher order accumulating interpolation, better alias suppression No mirroring Lines are mirrored Note 1. X = don't care. Table 138 Vertical chrominance phase offset `00'; register set A [B8H[7:0]] and B [E8H[7:0]] VERTICAL CHROMINANCE PHASE OFFSET Offset = 0 Offset = Offset = 32 32 = 1 line 255 lines 32 YMODE 0 1 X X X X 0 1 CONTROL BITS D7 TO D0 YPC07 0 0 1 YPC06 0 0 1 YPC05 0 1 1 YPC04 0 0 1 YPC03 0 0 1 YPC02 0 0 1 YPC01 0 0 1 YPC00 0 0 1 Table 139 Vertical luminance phase offset `00'; register set A [BCH[7:0]] and B [ECH[7:0]] VERTICAL LUMINANCE PHASE OFFSET Offset = 0 Offset = Offset = 32 32 = 1 line 255 lines 32 CONTROL BITS D7 TO D0 YPY07 0 0 1 YPY06 0 0 1 YPY05 0 1 1 YPY04 0 0 1 YPY03 0 0 1 YPY02 0 0 1 YPY01 0 0 1 YPY00 0 0 1 2004 Jul 22 158 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 16 PROGRAMMING START SET-UP 16.1 Decoder part SAF7118 The given values force the following behaviour of the SAF7118 decoder part: * The analog input AI11 expects an NTSC M, PAL B, D, G, H and I or SECAM signal in CVBS format; analog anti-alias filter and AGC active * Automatic field detection enabled * Standard ITU 656 output format enabled on expansion (X) port * Contrast, brightness and saturation control in accordance with ITU standards * Adaptive comb filter for luminance and chrominance activated * Pins LLC, LLC2, XTOUT, RTS0, RTS1 and RTCO are set to 3-state. Table 140 Decoder part start set-up values for the three main standards SUB ADDRESS (HEX) 00 01 02 03 04 05 06 07 08 09 0A 0B 0C 0D 0E 0F 10 11 VALUES (HEX) REGISTER FUNCTION chip version increment delay analog input control 1 analog input control 2 analog input control 3 analog input control 4 horizontal sync start horizontal sync stop sync control luminance control luminance brightness control luminance contrast control chrominance saturation control chrominance hue control chrominance control 1 chrominance gain control chrominance control 2 mode/delay control ID7 to ID4 X, WPOFF, GUDL1, GUDL0 and IDEL3 to IDEL0 FUSE1, FUSE0 and MODE5 to MODE0 X, HLNRS, VBSL, CPOFF, HOLDG, GAFIX, GAI28 and GAI18 GAI17 to GAI10 GAI27 to GAI20 HSB7 to HSB0 HSS7 to HSS0 AUFD, FSEL, FOET, HTC1, HTC0, HPLL, VNOI1 and VNOI0 BYPS, YCOMB, LDEL, LUBW and LUFI3 to LUFI0 DBRI7 to DBRI0 DCON7 to DCON0 DSAT7 to DSAT0 HUEC7 to HUEC0 CDTO, CSTD2 to CSTD0, DCVF, FCTC, AUTO0 and CCOMB ACGC and CGAIN6 to CGAIN0 OFFU1, OFFU0, OFFV1, OFFV0, CHBW and LCBW2 to LCBW0 COLO, RTP1, HDEL1, HDEL0, RTP0 and YDEL2 to YDEL0 47 C0 10 90 90 EB E0 98 40 80 44 40 00 89 2A 0E 00 BIT NAME(1) NTSC M PAL B, D, G, H AND I read only 47 C0 10 90 90 EB E0 98 40 80 44 40 00 81 2A 06 00 47 C0 10 90 90 EB E0 98 1B 80 44 40 00 D0 80 00 00 SECAM 2004 Jul 22 159 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SUB ADDRESS (HEX) 12 13 14 15 16 17 18 19 1A to 1D 1E 1F Note 1. All X values must be set to logic 0. SAF7118 VALUES (HEX) REGISTER FUNCTION RT signal control RT/X port output control analog/ADC/compatibility control VGATE start, FID change VGATE stop miscellaneous, VGATE configuration and MSBs raw data gain control raw data offset control reserved status byte 1 video decoder status byte 2 video decoder BIT NAME(1) NTSC M RTSE13 to RTSE10 and RTSE03 to RTSE00 RTCE, XRHS, XRVS1, XRVS0, HLSEL and OFTS2 to OFTS0 CM99, UPTCV, AOSL1, AOSL0, XTOUTE, AUTO1, APCK1 and APCK0 VSTA7 to VSTA0 VSTO7 to VSTO0 LLCE, LLC2E, LATY2 to LATY0, VGPS, VSTO8 and VSTA8 RAWG7 to RAWG0 RAWO7 to RAWO0 X, X, X, X, X, X, X, X -, HLCK, SLTCA, GLIMT, GLIMB, WIPA, DCSTD1 and DCSTD0 INTL, HLVLN, FIDT, -, TYPE3, COLSTR, COPRO and RDCAP 00 00 00 11 FE C0 40 80 00 PAL B, D, G, H AND I 00 00 00 11 FE C0 40 80 00 read only read only SECAM 00 00 00 11 FE C0 40 80 00 2004 Jul 22 160 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 16.2 Component video part and interrupt mask SAF7118 The given values force the following behaviour of the SAF7118 component video part: * The analog inputs AI11, AI21, AI31 and AI41 expect an RGBS signal; analog anti-alias filters and AGC for the sync channel active * For other settings see decoder part (Section 16.1). Table 141 Component video part and interrupt mask start set-up values SUB ADDRESS (HEX) 23 24 25 26 to 28 29 2A 2B 2C 2D 2E 2F Note 1. All X values must be set to logic 0. REGISTER FUNCTION analog input control 5 analog input control 6 analog input control 7 reserved component delay component contrast control component saturation control interrupt mask 1 interrupt mask 2 interrupt mask 3 BIT NAME(1) AOSL2, ADPE, EXCLK, REFA, X, EXMCE, GAI48 and GAI38 GAI37 to GAI30 GAI47 to GAI40 X, X, X, X, X, X, X, X FSWE, FSWI, FSWDL1, FSWDL0, CMFI, CPDL2 to CPDL0 CCON7 to CCON0 CSAT7 to CSAT0 X, X, X, MVPSV, MPPV, MCCV, X and MERROF X, MHLCK, X, X, X, X, MDCSTD1 and MDCSTD0 MINTL, MHLVLN, MFIDT, X, MTYPE3, MCOLSTR, MCOPRO and MRDCAP VALUES (HEX) 00 90 90 00 40 80 40 47 00 00 00 component brightness control CBRI7 to CBRI0 2004 Jul 22 161 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 16.3 Audio clock generation part SAF7118 The given values force the following behaviour of the SAF7118 audio clock generation part: * Used crystal is 24.576 MHz * Expected field frequency is 59.94 Hz (e.g. NTSC M standard) * Generated audio master clock frequency at pin AMCLK is 256 x 44.1 kHz = 11.2896 MHz * AMCLK is externally connected to AMXCLK [short-cut between pins P11 (72) and M12 (76)] * ASCLK = 32 x 44.1 kHz = 1.4112 MHz * ALRCLK is 44.1 kHz. Table 142 Audio clock part set-up values SUB ADDRESS (HEX) 30 31 32 33 34 35 36 37 38 39 3A 3B to 3F Note 1. All X values must be set to logic 0. START VALUES REGISTER FUNCTION audio master clock cycles per field; bits D7 to D0 audio master clock cycles per field; bits D15 to D8 audio master clock cycles per field; bits D17 and D16 reserved audio master clock nominal increment; bits D7 to D0 audio master clock nominal increment; bits D15 to D8 audio master clock nominal increment; bits D21 to D16 reserved clock ratio AMXCLK to ASCLK clock ratio ASCLK to ALRCLK audio clock generator basic set-up reserved BIT NAME(1) 7 ACPF7 to ACPF0 ACPF15 to ACPF8 X, X, X, X, X, X, ACPF17 and ACPF16 X, X, X, X, X, X, X, X ACNI7 to ACNI0 ACNI15 to ACNI8 X, X, ACNI21 to ACNI16 X, X, X, X, X, X, X, X X, X, SDIV5 to SDIV0 X, X, LRDIV5 to LRDIV0 X, X, X, X, APLL, AMVR, LRPH, SCPH X, X, X, X, X, X, X, X 1 1 0 0 1 1 0 0 0 0 0 0 6 0 1 0 0 1 1 0 0 0 0 0 0 5 1 0 0 0 0 0 1 0 0 0 0 0 4 1 1 0 0 0 0 1 0 0 1 0 0 3 1 1 0 0 1 1 1 0 0 0 0 0 2 1 1 0 0 1 1 0 0 0 0 0 0 1 0 1 1 0 0 0 1 0 1 0 0 0 0 0 1 0 0 1 0 0 0 1 0 0 0 HEX BC DF 02 00 CD CC 3A 00 03 10 00 00 2004 Jul 22 162 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 16.4 Data slicer and data type control part SAF7118 The given values force the following behaviour of the SAF7118 VBI data slicer part: * Closed captioning data are expected at line 21 of field 1 (60 Hz/525 line system) * All other lines are processed as active video * Sliced data are framed by ITU 656 like SAV/EAV sequence (DID[5:0] = 3EH MSB of SAV/EAV = 1). Table 143 Data slicer start set-up values SUB ADDRESS (HEX) 40 41 to 53 54 55 to 57 58 59 5A 5B 5C 5D 5E 5F 60 61 62 Notes 1. All X values must be set to logic 0. 2. Changes for 50 Hz/625 line systems: subaddress 5AH = 03H and subaddress 5BH = 03H. START VALUES REGISTER FUNCTION slicer control 1 line control register 2 to 20 line control register 21 line control register 22 to 24 programmable framing code horizontal offset for slicer vertical offset for slicer field offset and MSBs for horizontal and vertical offset reserved header and data identification code control reserved slicer status byte 0 slicer status byte 1 slicer status byte 2 BIT NAME(1) 7 X, HAM_N, FCE, HUNT_N, X, X, X, X LCRn_7 to LCRn_0 (n = 2 to 20) LCR21_7 to LCR21_0 LCRn_7 to LCRn_0 (n = 22 to 24) FC7 to FC0 HOFF7 to HOFF0 VOFF7 to VOFF0 FOFF, RECODE, X, VOFF8, X, HOFF10 to HOFF8 X, X, X, X, X, X, X, X FVREF, X, DID5 to DID0 0 1 0 1 0 0 0 1 0 0 0 0 6 1 1 1 1 0 1 0 0 0 0 0 0 5 0 1 0 1 0 0 0 0 0 1 0 0 4 0 1 1 1 0 0 0 0 0 1 0 0 3 0 1 1 1 0 0 0 0 0 1 0 0 2 0 1 1 1 0 1 1 0 0 1 0 0 1 0 1 1 1 0 1 1 1 0 1 0 0 0 0 1 1 1 0 1 0 1 0 0 0 0 HEX 40 FF 5F FF 00 47 06(2) 83(2) 00 3E 00 00 sliced data identification code X, X, SDID5 to SDID0 X, X, X, X, X, X, X, X -, FC8V, FC7V, VPSV, PPV, CCV, -, - -, -, F21_N, LN8 to LN4 LN3 to LN0, DT3 to DT0 read-only register read-only register read-only register 2004 Jul 22 163 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 16.5 Scaler and interfaces 16.5.1 TRIGGER CONDITION SAF7118 Table 144 shows some examples for the scaler programming with: * prsc = prescale ratio * fisc = fine scale ratio * vsc = vertical scale ratio. number of input pixel The ratio is defined as: ---------------------------------------------------------number of output pixel In the following settings the VBI data slicer is inactive. To activate the VBI data slicer, VITX[1:0] 86H[7:6] has to be set to `11'. Depending on the VBI data slicer settings, the sliced VBI data is inserted after the end of the scaled video lines, if the regions of VBI data slicer and scaler overlaps. To compensate the running-in of the vertical scaler, the vertical input window lengths are extended by 2 to 290 lines, respectively 242 lines for XS, but the scaler increment calculations are done with 288, respectively 240 lines. 16.5.3 EXAMPLES For trigger condition STRC[1:0] 90H[1:0] not equal to `00'. If the value of (YO + YS) is greater than or equal to 262 (NTSC), respectively 312 (PAL) the output field rate is reduced to 30 Hz, respectively 25 Hz. Horizontal and vertical offsets (XO and YO) have to be used to adjust the displayed video in the display window. As this adjustment is application dependent, the listed values are only dummy values. 16.5.2 MAXIMUM ZOOM FACTOR The maximum zoom factor is dependent on the back-end data rate and therefore back-end clock and data format dependent (8 or 16-bit output). The maximum horizontal zoom is limited to approximately 3.5, due to internal data path restrictions. Table 144 Example of configurations EXAMPLE NUMBER 1 SCALER SOURCE AND REFERENCE EVENTS analog input to 8-bit I port output, with SAV/EAV codes, 8-bit serial byte stream decoder output at X port; acquisition trigger at falling edge vertical and rising edge horizontal reference signal; H and V gates on IGPH and IGPV, IGP0 = VBI sliced data flag, IGP1 = FIFO almost full, level 24, IDQ qualifier logic 1 active INPUT OUTPUT WINDOW WINDOW SCALE RATIOS 720 x 240 720 x 240 prsc = 1; fisc = 1; vsc = 1 2 analog input to 16-bit output, without SAV/EAV codes, Y on 704 x 288 768 x 288 prsc = 1; I port, CB-CR on H port and decoder output at X port; fisc = 0.91667; acquisition trigger at falling edge vertical and rising edge vsc = 1 horizontal reference signal; H and V-pulses on IGPH and IGPV, output FID on IGP0, IGP1 fixed to logic 1, IDQ qualifier logic 0 active X port input 8-bit with SAV/EAV codes, no reference signals on XRH and XRV, XCLK as gated clock; field detection and acquisition trigger on different events; acquisition triggers at rising edge vertical and rising edge horizontal; I port output 8-bit with SAV/EAV codes like example number 1 X port and H port for 16-bit Y-CB-CR 4 : 2 : 2 input (if no 16-bit output selected); XRH and XRV as references; field detection and acquisition trigger at falling edge vertical and rising edge horizontal; I port output 8-bit with SAV/EAV codes, but Y only output 720 x 240 352 x 288 prsc = 2; fisc = 1.022; vsc = 0.8333 3 4 720 x 288 200 x 80 prsc = 2; fisc = 1.8; vsc = 3.6 2004 Jul 22 164 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input Table 145 Scaler and interface configuration example I2C-BUS ADDRESS (HEX) Global settings 80 83 84 85 86 87 88 task enable, IDQ and back-end clock definition XCLK output phase and X port output enable IGPH, IGPV, IGP0 and IGP1 output definition signal polarity control and I port byte swapping FIFO flag thresholds and video/text arbitration ICLK and IDQ output phase and I port enable power save control and software reset 10 01 A0 10 45 01 F0 - - - - - - - - - - - 16 - 720 - 10 - 242 - 720 - 240 - 10 01 C5 09 40 01 F0 - - - - - - - - - - - 16 - 704 - 10 - 290 - 768 - 288 - 10 00 A0 10 45 01 F0 - - - - - - - - - - - 16 - SAF7118 EXAMPLE 1 EXAMPLE 2 EXAMPLE 3 EXAMPLE 4 MAIN FUNCTIONALITY HEX DEC HEX DEC HEX DEC HEX DEC 10 00 A0 10 45 01 F0 - - - - - - - - - - - 16 - 720 - 10 - 290 - 200 - 80 - Task A: scaler input configuration and output format settings 90 91 92 93 task handling scaler input source and format definition reference signal definition at scaler input I port output formats and configuration 00 08 10 80 00 08 10 40 00 18 10 80 00 38 10 84 Input and output window definition 94 95 96 97 98 99 9A 9B 9C 9D 9E 9F horizontal output (destination) window length (XD) vertical output (destination) window length (YD) vertical input (source) window length (YS) vertical input offset (YO) horizontal input (source) window length (XS) horizontal input offset (XO) 10 00 D0 02 0A 00 F2 00 D0 02 F0 00 10 00 C0 02 0A 00 22 01 00 03 20 01 10 00 D0 02 0A 00 F2 00 60 01 20 01 10 00 D0 02 0A 00 22 01 C8 00 50 00 720 - 10 - 242 - 352 - 288 - 2004 Jul 22 165 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input I2C-BUS ADDRESS (HEX) SAF7118 EXAMPLE 1 EXAMPLE 2 EXAMPLE 3 EXAMPLE 4 MAIN FUNCTIONALITY HEX DEC HEX DEC HEX DEC HEX DEC Prefiltering and prescaling A0 A1 A2 A4 A5 A6 integer prescale (value `00' not allowed) accumulation length for prescaler FIR prefilter and prescaler DC normalization scaler brightness control scaler contrast control scaler saturation control 01 00 00 80 40 40 - - - 128 64 64 01 00 00 80 40 40 - - - 128 64 64 02 02 AA 80 40 40 - - - 128 64 64 02 03 F2 80 11 11 - - - 128 17 17 Horizontal phase scaling A8 A9 AA AC AD AE horizontal phase offset chrominance Vertical scaling B0 B1 B2 B3 B4 B8 to BF vertical scaling mode control vertical phase offsets luminance and chrominance (need to be used for interlace correct scaled output) vertical scaling increment for chrominance vertical scaling increment for luminance 00 04 00 04 00 1024 - 1024 - - 00 04 00 04 00 1024 - 1024 - - 55 03 55 03 00 853 - 853 - - 66 0E 66 0E 01 3686 - 3686 - - horizontal phase offset luminance horizontal scaling increment for chrominance horizontal scaling increment for luminance 00 04 00 00 02 00 1024 - - 512 - - AA 03 00 D5 01 00 938 - - 469 - - 18 04 00 0C 02 00 1048 - - 524 - - 34 07 00 9A 03 00 1844 - - 922 - - start with B8 to BF at 00H, if there are no problems with the interlaced scaled output optimize according to Section 8.4.3.2 2004 Jul 22 166 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 17 PACKAGE OUTLINES HBGA156: plastic thermal enhanced ball grid array package; 156 balls; body 15 x 15 x 1.15 mm; heatsink SAF7118 SOT807-1 D D1 B A ball A1 index area j E1 E A A2 A1 detail X e1 e 1/2 e C v M C A B w M C b y1 C y P N M L K J H G F E D C B A shape optional (4x) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 e heatsink e2 1/2 e X 0 5 scale 10 mm DIMENSIONS (mm are the original dimensions) UNIT mm A max. 1.75 A1 0.5 0.3 A2 1.25 1.05 b 0.6 0.4 D 15.2 14.8 D1 13.2 12.8 E 15.2 14.8 E1 13.2 12.8 e 1 e1 13 e2 13 j 8 10 v 0.3 w 0.1 y 0.15 y1 0.35 OUTLINE VERSION SOT807-1 REFERENCES IEC JEDEC MS-034 JEITA EUROPEAN PROJECTION ISSUE DATE 03-03-06 2004 Jul 22 167 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input SAF7118 QFP160: plastic quad flat package; 160 leads (lead length 1.6 mm); body 28 x 28 x 3.4 mm; high stand-off height SOT322-2 c y X A 120 121 81 80 ZE e E HE A A2 A1 (A 3) Lp L detail X 41 1 bp D HD wM ZD B vM B 40 vM A wM bp pin 1 index 160 e 0 5 scale 10 mm DIMENSIONS (mm are the original dimensions) UNIT mm A max. 4.07 A1 0.50 0.25 A2 3.6 3.2 A3 0.25 bp 0.38 0.22 c 0.23 0.13 D (1) 28.1 27.9 E (1) 28.1 27.9 e 0.65 HD HE L 1.6 Lp 1.03 0.73 v 0.3 w 0.13 y 0.1 Z D(1) Z E (1) 1.5 1.1 1.5 1.1 7 o 0 o 31.45 31.45 30.95 30.95 Note 1. Plastic or metal protrusions of 0.25 mm maximum per side are not included. OUTLINE VERSION SOT322-2 REFERENCES IEC 135E12 JEDEC MS-022 JEITA EUROPEAN PROJECTION ISSUE DATE 00-01-19 03-02-25 2004 Jul 22 168 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 18 SOLDERING 18.1 Introduction to soldering surface mount packages SAF7118 To overcome these problems the double-wave soldering method was specifically developed. If wave soldering is used the following conditions must be observed for optimal results: * Use a double-wave soldering method comprising a turbulent wave with high upward pressure followed by a smooth laminar wave. * For packages with leads on two sides and a pitch (e): - larger than or equal to 1.27 mm, the footprint longitudinal axis is preferred to be parallel to the transport direction of the printed-circuit board; - smaller than 1.27 mm, the footprint longitudinal axis must be parallel to the transport direction of the printed-circuit board. The footprint must incorporate solder thieves at the downstream end. * For packages with leads on four sides, the footprint must be placed at a 45 angle to the transport direction of the printed-circuit board. The footprint must incorporate solder thieves downstream and at the side corners. During placement and before soldering, the package must be fixed with a droplet of adhesive. The adhesive can be applied by screen printing, pin transfer or syringe dispensing. The package can be soldered after the adhesive is cured. Typical dwell time of the leads in the wave ranges from 3 seconds to 4 seconds at 250 C or 265 C, depending on solder material applied, SnPb or Pb-free respectively. A mildly-activated flux will eliminate the need for removal of corrosive residues in most applications. 18.4 Manual soldering This text gives a very brief insight to a complex technology. A more in-depth account of soldering ICs can be found in our "Data Handbook IC26; Integrated Circuit Packages" (document order number 9398 652 90011). There is no soldering method that is ideal for all surface mount IC packages. Wave soldering can still be used for certain surface mount ICs, but it is not suitable for fine pitch SMDs. In these situations reflow soldering is recommended. 18.2 Reflow soldering Reflow soldering requires solder paste (a suspension of fine solder particles, flux and binding agent) to be applied to the printed-circuit board by screen printing, stencilling or pressure-syringe dispensing before package placement. Driven by legislation and environmental forces the worldwide use of lead-free solder pastes is increasing. Several methods exist for reflowing; for example, convection or convection/infrared heating in a conveyor type oven. Throughput times (preheating, soldering and cooling) vary between 100 seconds and 200 seconds depending on heating method. Typical reflow peak temperatures range from 215 C to 270 C depending on solder paste material. The top-surface temperature of the packages should preferably be kept: * below 225 C (SnPb process) or below 245 C (Pb-free process) - for all BGA, HTSSON-T and SSOP-T packages - for packages with a thickness 2.5 mm - for packages with a thickness < 2.5 mm and a volume 350 mm3 so called thick/large packages. * below 240 C (SnPb process) or below 260 C (Pb-free process) for packages with a thickness < 2.5 mm and a volume < 350 mm3 so called small/thin packages. Moisture sensitivity precautions, as indicated on packing, must be respected at all times. 18.3 Wave soldering Fix the component by first soldering two diagonally-opposite end leads. Use a low voltage (24 V or less) soldering iron applied to the flat part of the lead. Contact time must be limited to 10 seconds at up to 300 C. When using a dedicated tool, all other leads can be soldered in one operation within 2 seconds to 5 seconds between 270 C and 320 C. Conventional single wave soldering is not recommended for surface mount devices (SMDs) or printed-circuit boards with a high component density, as solder bridging and non-wetting can present major problems. 2004 Jul 22 169 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 18.5 Suitability of surface mount IC packages for wave and reflow soldering methods PACKAGE(1) BGA, HTSSON..T(3), LBGA, LFBGA, SQFP, SSOP..T(3), TFBGA, USON, VFBGA DHVQFN, HBCC, HBGA, HLQFP, HSO, HSOP, HSQFP, HSSON, HTQFP, HTSSOP, HVQFN, HVSON, SMS PLCC(5), SO, SOJ LQFP, QFP, TQFP SSOP, TSSOP, VSO, VSSOP CWQCCN..L(8), PMFP(9), WQCCN..L(8) Notes not suitable not suitable(4) suitable not not recommended(5)(6) recommended(7) SAF7118 SOLDERING METHOD WAVE REFLOW(2) suitable suitable suitable suitable suitable not suitable not suitable 1. For more detailed information on the BGA packages refer to the "(LF)BGA Application Note" (AN01026); order a copy from your Philips Semiconductors sales office. 2. All surface mount (SMD) packages are moisture sensitive. Depending upon the moisture content, the maximum temperature (with respect to time) and body size of the package, there is a risk that internal or external package cracks may occur due to vaporization of the moisture in them (the so called popcorn effect). For details, refer to the Drypack information in the "Data Handbook IC26; Integrated Circuit Packages; Section: Packing Methods". 3. These transparent plastic packages are extremely sensitive to reflow soldering conditions and must on no account be processed through more than one soldering cycle or subjected to infrared reflow soldering with peak temperature exceeding 217 C 10 C measured in the atmosphere of the reflow oven. The package body peak temperature must be kept as low as possible. 4. These packages are not suitable for wave soldering. On versions with the heatsink on the bottom side, the solder cannot penetrate between the printed-circuit board and the heatsink. On versions with the heatsink on the top side, the solder might be deposited on the heatsink surface. 5. If wave soldering is considered, then the package must be placed at a 45 angle to the solder wave direction. The package footprint must incorporate solder thieves downstream and at the side corners. 6. Wave soldering is suitable for LQFP, TQFP and QFP packages with a pitch (e) larger than 0.8 mm; it is definitely not suitable for packages with a pitch (e) equal to or smaller than 0.65 mm. 7. Wave soldering is suitable for SSOP, TSSOP, VSO and VSSOP packages with a pitch (e) equal to or larger than 0.65 mm; it is definitely not suitable for packages with a pitch (e) equal to or smaller than 0.5 mm. 8. Image sensor packages in principle should not be soldered. They are mounted in sockets or delivered pre-mounted on flex foil. However, the image sensor package can be mounted by the client on a flex foil by using a hot bar soldering process. The appropriate soldering profile can be provided on request. 9. Hot bar or manual soldering is suitable for PMFP packages. 2004 Jul 22 170 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 19 DATA SHEET STATUS LEVEL I DATA SHEET STATUS(1) Objective data PRODUCT STATUS(2)(3) Development DEFINITION SAF7118 This data sheet contains data from the objective specification for product development. Philips Semiconductors reserves the right to change the specification in any manner without notice. This data sheet contains data from the preliminary specification. Supplementary data will be published at a later date. Philips Semiconductors reserves the right to change the specification without notice, in order to improve the design and supply the best possible product. This data sheet contains data from the product specification. Philips Semiconductors reserves the right to make changes at any time in order to improve the design, manufacturing and supply. Relevant changes will be communicated via a Customer Product/Process Change Notification (CPCN). II Preliminary data Qualification III Product data Production Notes 1. Please consult the most recently issued data sheet before initiating or completing a design. 2. The product status of the device(s) described in this data sheet may have changed since this data sheet was published. The latest information is available on the Internet at URL http://www.semiconductors.philips.com. 3. For data sheets describing multiple type numbers, the highest-level product status determines the data sheet status. 20 DEFINITIONS Short-form specification The data in a short-form specification is extracted from a full data sheet with the same type number and title. For detailed information see the relevant data sheet or data handbook. Limiting values definition Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 60134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability. Application information Applications that are described herein for any of these products are for illustrative purposes only. Philips Semiconductors make no representation or warranty that such applications will be suitable for the specified use without further testing or modification. 21 DISCLAIMERS Life support applications These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. Philips Semiconductors customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Philips Semiconductors for any damages resulting from such application. Right to make changes Philips Semiconductors reserves the right to make changes in the products including circuits, standard cells, and/or software described or contained herein in order to improve design and/or performance. When the product is in full production (status `Production'), relevant changes will be communicated via a Customer Product/Process Change Notification (CPCN). Philips Semiconductors assumes no responsibility or liability for the use of any of these products, conveys no licence or title under any patent, copyright, or mask work right to these products, and makes no representations or warranties that these products are free from patent, copyright, or mask work right infringement, unless otherwise specified. 2004 Jul 22 171 Philips Semiconductors Product specification Multistandard video decoder with adaptive comb filter and component video input 22 PURCHASE OF PHILIPS I2C COMPONENTS SAF7118 Purchase of Philips I2C components conveys a license under the Philips' I2C patent to use the components in the I2C system provided the system conforms to the I2C specification defined by Philips. This specification can be ordered using the code 9398 393 40011. 2004 Jul 22 172 Philips Semiconductors - a worldwide company Contact information For additional information please visit http://www.semiconductors.philips.com. Fax: +31 40 27 24825 For sales offices addresses send e-mail to: sales.addresses@www.semiconductors.philips.com. (c) Koninklijke Philips Electronics N.V. 2004 SCA76 All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights. Printed in The Netherlands R21/02/pp173 Date of release: 2004 Jul 22 Document order number: 9397 750 13496 |
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